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PARTIAL SYLLABIC LISTS
CLINICAL MORPHOLOGIES
The Blood, Sputum, Feces, Skin, Urine, Vomitus, Foods,
including Potable Waters, Ice and the Air,
and the Clothing (After Salisbury),
EPHJRAHVT CUTTER,
M.D. Harvard and University of Pennsylvania, A.M. Yale,
LL.D. Iowa, Hon. F.S.Sc. (London)
Principal Medical Department, American Institute of Micrology; First to Photograph
Consumptive Blood; Inventor Several Forms of the Clinical Microscope,
The Cam Fine Adjustment, etc., etc.
Corresponding Member Societe Beige de Microscopie and Gynecological Society of Boston ;
Associate Member Philosophical Society of Great Britain; Honorary Member
California State Medical Society; Member American Society of
Microscopists, American Medical Association, etc.
Author Boylston Prize Essay, 1857; Primer of the Clinical Microscope; What I Use the
Microscope For; Morphology of Diseased Blood; Morphology of Rheumatic Blood
(Ninth International Medical Congress); Morphology of Potatoes, Cooked; Crypta
Syphilitica; Monstrous Spermatozoa; Micrographical Contribution as to the
Vegetable Nature of Croup; Tubercle Parasite; Microscopical Examination
of Ice; Suspicious Organisms in the Croton; Beri-Beri; Trichina; Butter;
Effects of Alcohol on Brain Tissues; Action of Alcohol on the Blood;
AsthmatosCiliaris; Diphtheria and Potatoes; Use of Microscope
in Consumption; Throat Syphilis and Tubercle according to
Salisbury; Tolles' 1-75 inch Objective, its History, Use,
and Construction; Amoeboid Movements of the
White Blood-Corpuscle; A New Sign of the
Pre-Embolic State; Food Stuffs under
the Microscope, etc., etc.
u A capacity to do good not only gives a title to it. but makes the doing of it a duty."
Duke of Brandenburg, 1691
NEW YORK
THE ARISTON, BROADWAY AND 55TH STREET
PUBLISHED BY THE AUTHOR
I8S8
a«\?
Copyright by
EPHRAIM CUTTER,
P«ES9 OF
STETTINER, LAMBERT A CO,
22, 24 & 2t READE ST.,
NEW YORK.
gexlicattou*
This work is respectfully dedicated to the following,
who have shown themselves searchers after medical
truth and courteous to co-laborers.
Benjamin Cutter, M.D., A.M., in
memoriam, summa laude
J. Marion Sims, M.D., LL.D., in
memoriam, summa laude
E. S. Gaillard, M.D., LL.D., in
memoriam, summa laude
Louis Elsberg, M.D., in memoriam,
summa laude
George Waterhouse Garland,
M.D., in memoriam
George M. Beard, M.D., in me-
moriam, summa laude
S. D. Gross, M.D., LL.D., D.C.L.,
in memoriam, summa laude
Frank H. Hamilton, M.D.,LL.D.,
in memoriam, summa laude
James R. Nichols, M.D., in memo-
riam, summa laude
Washington L. Atlee, M.D., in
memoriam, summa laude
Professor L. A. Sayre, M.D.
Professor T. G. Thomas, M.D.
Professor Albert Vander Veer,
M.D., Ph.D.
Professor R. J. Nunn, M.D.
Professor T. E. Murrill, M.D.
Professor T. E. Satterthwaite,
M.D.
Professor Joseph Jones, M.D.
Professor Jacob Cooper, M.D.,
Ph.D., J. CD., S.T.D.
Professor Wm. B.Atkinson, M.D.,
A.M.
Professor Byron Stanton, M.D.
Professor J. Solis Cohen, M.D.
Professor W. W. Dawson, M.D.
Professor Samuel B. Ward, M.D.,
Ph.D.
Professor Joseph Leidy, M.D.
Professor James P.. Boyd, M.D.,
M.A.
Professor D. Hayes Agnew M.D.r
LL.D.
Professor D. Humphreys Storer,
M.D., LL.D.
Professor H. M. Field, M D
Eugene Van Slyke, M.D.
Israel H. Taylor, M.D.
George D. Dowkontt, M.D.
Ezra P. Allen, M.D., Ph.D.
David Prince, M.D.
Alfred C Garratt, M.D.
G. L. Simmons, M.D.
W. Symington Brown, M.D.
Jonas C. Harris, M.D.
Austin W. Thompson, M.D.
Samuel W. Abbott, M.D., M.A.
J. J. Mulheron, M.D.
R. E. Thompson, M.D., F.R.C.P.
Lond., summa laude
Henry O. Marcy, M.D., LL.D.
J. N. Hyde, M.D.
Landon B. Edwards, M.D.
Sir James Grant
Professor Aust-Lawrence, M.D.
D. H. Goodwillie, M.D.
Professor A. B. Arnold, M.D.
R. U. Piper, M.D.
W. R. Weisager, M.D.
Professor Domingos Freire, M.D.
Caleb Green, M.D.
A. F. Pattee, M.D.
Fr. Ecklund, M.D.
Professor E. A. Wood, M.D.
Professor M. C. White, M.D.
M. G. Wheeler, M.D.
Henry C Bunce, M.D.
Sir Morell Mackenzie
IV DEDICATION.
TO MY INSTRUCTORS
James H. Salisbury, M.D., LL.D., Professor Oliver Wendell
maxima laude Holmes, M.D., LL.D., D.C.L.
Professor Paulus F. Reinsch Rev. Joseph Cook
Professor J. P. Cooke, M.D. George B. Harriman, D.D.S.
Robert B. Tolles, in memoriam
INTRODUCTION TO THE MOR-
PHOLOGIES.
It is now over ten years since the writer first
applied this word to the account (logos) of the
forms (morphos) found in the blood, sputum,
faeces, urine, etc., and its general adaptation
seems to justify the use of the term. It was
employed to facilitate the introduction of the
thoughts and results embraced in The Relation
of Alimentation to Disease* by J. H. Salisbury,
M.D., LL.D., the master discoverer and ex-
plorer.
The morphologies of his discoveries are over
twenty-five years old. The number of people
who have been cured by the thorough and
systemic plans based on them is such that
there is no need of apologizing for bringing
them more prominently to notice, but rather of
apologizing that they have been kept back so
long. The writer has not ceased night and
day to urge their publication, and he is per-
mitted to hint gently that, if what has now been
issued is well received, much more valuable
* New York: J. H. Vail & Co., 1888.
VI INTRODUCTION TO THE MORPHOLOGIES.
treasures will be dispensed from the store-
house to all who ask for them.
Those who gain a tolerable knowledge of
these lists will expect, among other things,
to diagnosticate consumption of the lungs in
(i) The pretubercular state; (2) In the inva-
sion stage ; (3) In the breaking down stage.
To diagnosticate syphilis at once. To diag-
nosticate rheumatism, in its various forms. To
diagnosticate fibraemia, anaemia, leucocythaemia,
malaria, diseases of fatty degeneration, scle-
rosis, locomotor ataxy, impending apoplexy,
and paraplegia, etc., etc. To diagnosticate a
state of perfect health, a tendency to diseased
conditions, etc., etc.
Since nearly a quarter of a century has been
spent on these morphologies, it cannot be claim-
ed that they are hastily gotten up ; still the lists
are all partial, subject to addition and subtrac-
tion, as need requires. They may be taken to
represent the actual state of knowledge at the
present day, which is quite an advance over a
quarter of a century ago.
PREFACE. •
For some years the writer has needed a pub-
lished list of the clinical morphologies for the
use of his pupils. He has waited long to have
the lists complete, but in vain. Complete
knowledge of any subject is about as rare as
a completed city. Knowledge is ever on the
increase, like most of our cities. We use our
cities even if incomplete, so must we use our
knowledge as far as it goes.
One object of this work is to show the
height and depth, the length and breadth of
the so-called Salisbury plans; that they are en-
titled, to respectful hearing ; that they include
a wide survey and comprehensive grasp of the
world that comes in contact with our bodies,
outside and in ; that they have no narrowness
of range nor contraction of vision ; that they
deal with facts more than with opinions ; that
the tests to which they may be subject are close
at hand and near to reach. They are cis- not
transatla?itic.
These morphologies also show that the writer
has not ridden a one-horse hobby in satisfying
his mind of the truth of the plans named, but
Vlll PREFACE.
that he has endeavored to take broad views of
all the evidence in the matter before coming to
conclusions.
It has been suggested that the writer give a
short history of His relation to these subjects. In
justice to all concerned, and to make shorter
work, the personal pronoun will be used, mostly.
I began the use of the microscope as a means
of education and useful knowledge, if my mem-
ory serves me rightly, in the Sheffield Scien-
tific School of Yale College in 1850. The
winter of 1853-4 I spent in Professor J. P.
Cooke's private laboratory, working up the
morphologies of blood and urine, together with
their micro-chemistry. Besides him, I have
studied under Dr. O. W. Holmes, Col. J. J.
Woodward, G. B. Harriman, D.D.S., Pro-
fessor Paulus F. Reinsch, the highest author-
ity in algae; and Dr. James H. Salisbury.
The last gentleman excels all others in the
amount of original information which I have
found of priceless need and value in medicine.
Before studying medicine, I was inspired with
a desire to know all I could about the causes
of disease. Having, from a child, been in the
habit of accompanying, in his professional
rounds, my father, the late Dr. Benjamin Cut-
ter, of Woburn, Mass. (wrho honored his pro-
fession for forty years), I early took in the idea
that there was a great field of much-needed
effort, from the chance remarks he would drop
PREFACE. IX
when he resumed his seat in the carriage
(which I kept) after having seen some very
sick patients. He said often, " Oh, how I wish
we doctors knew more as to the real causes of
disease." This impulse was much strength-
ened by his telling me (when I informed him
that I did not want to study medicine to prac-
tice it, but only to know the causes of disease),
" Go ahead ; study all you can. I will help all
I can, but I want you to study these three
things.
" I. What is the cause of consumption.
" 2. What is the cause of the diseases of
women.
"3. What is the cause of diseases of the
nervous system.
" We doctors do not know anything about
them." And yet this was a surgeon who suc-
cessfully, without anaesthesia, opened the knee
joint and removed a free cartilage (assisted
only by the writer when twelve years old).
The present work is the outcome of this
paternal injunction. Advisedly, seriously, and
thoughtfully can it be now said, these three (3)
problems have been answered satisfactorily,
and we know that unhealthy alimentation
causes primarily all of these classes of disease.
In 1857, trie Boylston Prize was awarded
the writer for an essay on " Under what Cir-
cumstances do the Usual Signs Furnished by
PREFACE.
Auscultation and Percussion Prove Falla-
cious ? "
In 1858, the writer invented a laryngoscope,
which was made by Alvan Clarke & Son, the
great telescope makers.
In 1866, the writer took the first photograph
of the vocal cords (his own), which showed the
thyroid insertion.
In 1866, he demonstrated to large numbers
his own larynx in situ naturali, and the poste-
rior nares, showing either Eustachian tubes at
will, the vomer, and turbinated bones, and first
demonstrated the erection of the mucous mem-
brane of the turbinated bones in smelling odor-
ous or malodorous substances.
Before i860, he travelled over five thousand
miles to see if alcoholism could be connected
with consumption of the lungs.
In 1867, I visited Dr. Salisbury to learn how
to study malaria. At that time, I found he had
gone one step farther than I, and connected the
vinegar plant with consumption. Thus he sup-
plied the missing link to my chain, and, after
repeated and careful observations, I came to
learn the truth of this new doctrine in the ac-
tual treatment and cure of cases, and ever since
have endeavored to make it known in proper
ways, so far as I could.
Finding Dr. S.'s drawings denounced and
ridiculed, and, of course, rejected, and stung to
think that this work should be deemed an idle
PREFACE. XI
tale, I set myself to work to photograph as
many of the appearances in consumptive blood
as I could. Probably this was the first attempt
of this kind. Never before this had I known
of any blood being photographed save for
medico-legal purposes. I found the subject
very much hampered with details which I
thought should be done away with. Feeling
the greatness of the work, and that it should be
done before my eyesight and faculties were too
old, I gave up a fine country practice and set-
tled in Cambridge, Mass., as I thought this seat
of learning would be the most favorable for the
encouragement and prosecution of my work.
The winter of 1875-6 was spent in working up
micro-photography. Fortunately I came across
Dr. G. B. Harriman, Surgeon-dentist, of Bos-
ton, who possessed magnificent objectives made
by R. B. Tolles, among them the 1-50 inch and
1-75 inch. He entered into the work heartily,
and together we took micro-photographs of con-
sumptive blood morphology for the first time
and with the highest powers ever used up to
that time and since (so far as I can ascertain), and
which have been pronounced good in Europe.
The account of this work may be found in
the American Journal of Science, New Haven,
August, 1879; Scientific American Stipple-
ment, September, 1879; Journal of Micro-
graphie, Paris, 1879. These photographs have
been placed on the screen before the American
XII PREFACE.
Medical Association; Chicago Medical Society;
Academy of Medicine, Virginia ; Academy of
Sciences, New York; Albany Medical College;
Monday Lectureship, Boston, Rev. Joseph
Cook; Gynecological Society of Boston, and
many other bodies. These things are named
to show that I am in earnest, for none would
have done this unless he was sincere and meant
what he said.
In 1876, Professor Paulus F. Reinsch was
introduced to me at the Botanical Garden, in
Cambridge, as the greatest algologist. Care-
ful study with him has confirmed my views
on these so-called Salisbury plans. So many
cures have followed, that I feel it would be a
crime in me not to testify to what I know, and
how I have been set right upon the three tasks
propounded by my honored and honorable fa-
ther more than thirty years ago, and which, so
far as in me lies, I have tried to solve or have
solved. I am a co-witness with Dr. Salis-
bury ; " that in the mouth of two or three witnes-
ses every word may be established." I charge
therefore those to whom these presents may
come to look over the evidence, and take time
before they treat these things as "idle tales."
If the "Imperial Granum" which I have shown
morphologically to be common flour, and which
the Connecticut agricultural experiment sta-
tion has also shown to be common flour, selling
at $1.00 per pound, while it is worth from
PREFACE. Xlll
$0,025 to $0.05, is used amd indorsed by the
medical profession (so that its proprietors have
become rich and use fifty-two barrels of flour
in one batch), on statements that wilt before
the microscope and crucible, does it look well
for the same noble profession to treat the plans
here indorsed, which stand the tests of the mi-
croscope and chemistry, as an " idle tale ? "
I have nothing but good feeling or words
towards those who honestly differ, but I do
dislike to see physicians led by persons who
not only have no medical education, but also ad-
vertise untruths and at the same time consider
these plans as "idle tales," and neglect to look
into the evidence which has stood for nearly a
quarter of a century, and which affects the weal
or woe, not only of the public, but of the profes-
sion and the very gentlemen themselves.
Be this as it may, in time to come, none can
accuse me of not having tried to discharge the
duties which every physician owes to his fel-
lows, to wit : if any physician knows or thinks
he knows anything which will better the prac-
tice of medicine, there is a moral obligation for
him to discharge by making it known, and so
long as the rules of courtesy are observed by
the contributor, he is entitled to a courteous
hearing. Any departure from this savors of
savagery and puts the doer at once out of the
pale of civilized ethics.
May ist, 1888.
CONTENTS.
Dedication, .....
Introduction, . . . . .
Preface, .....
I. The Morphology of the Blood — Mode of Study,
A. General list of the Morphology of the Blood in
Health and Disease, 3; The Colored Corpuscles,
3; The Colorless Corpuscles 4; The Serum,
B. Morphology of the Blood in Health,
C. Movements and Changes of the Blood in Dying,
D. Morphology of the Blood in Consumption of the
Lungs ; Use, 9 ; First or Incubative Stage 10 ;
Second Stage, of Transmission, 10; the Third Stage
or Stage of Tubercular Deposition 12 ; Fourth
Stage, Interstitial Death,
E. The Morphology of the Blood in Rheumatism,
F. Fibraemia, ....
G. Thrombosis, ....
H. Embolism, ....
I. Pre-embolic State,
J. Anaemia, .
K. Pernicious Anaemia, .
L. Morphology of the Blood in Syphilis,
M. Morphology of the Blood in Eczema,
N. Morphology of the Blood in Scrofula,
O. Morphology of the Blood in Malaria,
P. Hereditary Taints,
Q. Cancer, ....
R. Morphology of the Blood in Variola and Vaccinia,
S. Morphology of the Blood in Typhoid Fever,
T. Morphology of the Blood in Scarlet Fever and Diph
theria, .....
U. Morphology of the Blood in Fatty Degeneration,
V. Morphology of the Blood in Fibrous Consumption,
PAGET
iii.-iv.
v.-vi.
vii.-xiii.
1
12
13
17
17
18
18
18
19
J9
20
21
21
22
23
23
23
24
24
25
XVI
CONTENTS.
W. Cholestersemia, . . . . 25
X. Morphology of the Blood in Carbuncle, . 26
Y. Morphology of the Blood in Yellow Fever, . . .26
Z. Leucocythaemia, .... 26
II. Morphology of the Sputum, . . . 27
III. Morphology of the Feces, . . . '33
IV. Morphology of the Skin, . . . . 38
V." Morphology of the Urine, ... 43
VI. Morphology of the Vomitus, . . . .48
VII. Morphology of Foods, ... .49
A. Waters of Lakes, Ponds and Water sheds; Hydrant
Waters, 49; List, 50; Appendix, . . 54
B. Waters of Springs and Wells unconnected with Lakes
or Ponds, ..... 58
C. Ice, 63; List, 64; Appendix, . . . . 65
D. Air, 70; List, . . . . .72
E. Morphology of Foods; Animal and Vegetable, 74;
Vegetable: Uncooked, 74; Cooked, 75; in the
Feces, 75, 76, 77. Beefsteak: Uncooked, 76;
Cooked, 76; in the Feces, 76; Adulteration, 77;
Infants' Foods, ..... 78
VIII. Morphology of Clothing, ... .80
EXPLANATORY.
Though, as stated in the title, these partial syllabic lists are after Salisbury,
1 wish to emphasize that those who read this book should, in order to get
more information on the subjects noted, especially the blood, sputum, feces,
urine, and skin, consult the works of Dr. Salisbury here named:
i. " The Relation of Alimentation to Disease," octavo, pp. xi., 334, plates
19. New York, 1888: J. H. Vail & Co. (See " Clinical Morphologies,"
consumption of the lungs, pp. 9 to 13; fibrsemia, p. 17; anaemia, p. 18; perni-
cious anaemia, p. 19; fibrous consumption, p. 25; sputum, pp. 27 to 32; feces,
PP- 33 to 37.)
2. *' Microscopic Examinations of the Blood and Vegetations Found in Vari-
ola. Vaccine, and Typhoid Fever.'* 66 pages and 62 illustrations. New York,
1868. (See page 23, " Clin. Morphologies.")
3. " Remarks on the Structure, Functions, and Classification of the Parent
Gland Cells, with Microscopic Investigations Relative to the Causes of the
Several Varieties of Rheumatism and Directions for their Treatment." I plate
of illustrations. American Journal Medical Sciences, October, 1867, p. 19.
<See pp. 13, 14, 15, 16, 17, "Clin. Morphologies.")
4. " Vegetations Found in the Blood of Patients Suffering from Erysipelas."
Hallier, Zeitschrift fur Parasitenkunde, 1873, 8 illustrations.
5. " Infusorial Catarrh and Asthma." 18 illustrations, do., 1873.
6. " Description of Two New Algoid Vegetations, One of which Appears to
be the Specific Cause of Syphilis, and the Other of Gonorrhoea." Do., 1873.
Also Amer. Jour. Med. Set., 1867. (See pp. 19-20, " Clin. Morphologies.")
7. "Chroric Diarrhoea and its Complications, or the Diseases Arising in
Armies from a too Exclusive Use of Amylaceous Food, with Other Interesting
Matter Relating to the Diet and Treatment of these Abnormal Conditions,
and a New Army Ration Proposed with which this Large Class of Diseases
may be Avoided." The Ohio Surgeon-General's Report for 1864.
8. " Probable Source of the Steatozoon Folliculorum." St. Louis Medical
Reporter, January, 1869.
9. "Something about Cryptogams, Fermentation, and Disease." Do.,
February, 1879.
10. "Investigations, Chemical and Microscopical, Resulting in what Ap-
pears to be the Discovery of a new Function of the Spleen and Mesenteric
and Lymphatic Glands." Do., August, 1867, 29 pages.
XV111 EXPLANATORY.
11. "Discovery of Choiesterin and Serolin as Secretions in Health of the
Salivary, Tear, Mammary, and Sudorific Glands; of the Testis and Ovary; of
the Kidneys in Hepatic Derangements; of Mucous Membranes when Congest-
ed and Inflamed, and the Fluids of Ascites and that of Spina Bifida." Amer.
Jour, Med. Sci,y April, 1863, 2 plates, 17 pages.
12. " Remarks on Fungi, with an Account of Experiments Showing the In-
fluence of the Fungi of Wheat and Rye Straw on the Human System, and Some
Observations which Point to Them as the Probable Source of Camp Measles,
and Perhaps of Measles Generally." Do., July, 1862, 1 plate, 30 pages.
13. " Inoculating the Human System with Straw Fungi to Protect It Against
the Contagion of Measles, with Some Additional Observations Relating to the
Influence of Fungoid Growths in Producing Disease, and in the Fermentation
and Putrefaction of Organic Bodies." Do., October, 1862, 8 pages.
14. " Two Interesting Parasitic Diseases; One We Take from Sucking Kit-
tens and the Other from Sucking Puppies. Trichosis Felinus and T. Caninus."
Boston Medical and Surgical Journal, June 4th, 1868. 6 illustrations. Also
Zeitschrift fur Parasitenkunde, Hallier, Jena, 1875.
15. " Malaria," McNaughton prize essay, 1882. Octavo, pp. 152, plates 10.
New York: W. A. Kellogg, 1885. (See pp. 21, 22, " Clin. Morphologies.")
16. "Diphtheria, Its Cause and Treatment." G. A. Davis, Detroit. 3 plates,
1884. (See page 24, "Clin. Morphologies.")
Which are a partial list of his works.
THE MORPHOLOGY OF THE BLOOD.
MODE OF STUDY.
It is necessary to have the patient, the micro-
scope, the light, the means of withdrawal of the
blood — a lancet, spring lancet, the scarificator
of the writer, or a needle, which is not the best
thing — all together.
There is no such thing as taking the blood
home to examine. The changes are so rapid
that most of the important ones disappear in ten
minutes' time. Still, after these are gone, many
valuable points remain to be looked for.
Kind of blood. — The capillary — not the ven-
ous or arterial.
Site of withdrawal. — On the radial or ulnar
side of the forearm near the wrist. The skin
should be clean and free from hair. If dirty,,
wash with soap suds or ammonia water.
(It is well that the beginners should study
the skin surface, dirt, and epithelium, be-
fore looking at the blood.) Take the patient's
forearm in the hand, and make the skin tense
2 THE MORPHOLOGY OF THE BLOOD.
in the interval between the thumb and fore-
finger. A quick puncture is then made, about
one-eighth of an inch deep. The tension of
the grip will squeeze out a drop of blood. The
size of the drop should bear a direct relation to
the size of the cover. If there is too little
blood, the corpuscles will become crenated,
that is, wrinkled from a sort of protoplasmic
action induced by too much dryness in the
space about the blood. If there is too much
blood, the superfluity will float the cover about;
there will be too much thickness of the film,
and it will crowd the red corpuscles so much as
to render them indistinguishable. The excess
must be removed by a bibulant. Very much
depends on handling the drop of blood rightly.
When the drop evenly diffuses itself, it is pre-
sumed that the film is about uniform in thick-
ness, so that one can judge somewhat as to the
comparative number of corpuscles in each speci-
men. The process of transferring the blood
should take only a few seconds of time ; a frac-
tion should be sufficient.
Of course, the slide and cover should be
previously cleaned, and also the microscope
should be free from dirt and in focus ; as, after
a previous use, if the blood specimen is placed
on the stage, it will be in focus at once, and the
rapid movements, changes, and morphological
elements will be visible immediately.
The novice had better scrutinize carefully
THE MORPHOLOGY OF THE BLOOD. 3
everything he sees, not caring whether he
knows the name of the object or not.
A. GENERAL LIST OF THE MORPHOLOGY OF
THE BLOOD IN HEALTH AND DISEASE.
The Color of the Blood to the Unaided Eye,
Consistence of the Blood. Rapidity of Clot-
ting.
1. The colored corpuscles.
2. The colorless corpuscles.
3. The serum.
1 . The Colored Corpuscles.
In normal proportion.
In excess.
In diminished quantity.
Normal consistence.
Too soft, plastic, and sticky ; adhering to-
gether and being drawn out in thread-like pro-
longations.
Nummulated, like rolls of coin.
Not nummulated.
Evenly and loosely scattered over the field.
Slightly grouped.
In irregular, compact masses.
In ridges.
Color, clear, fresh, bright, ruddy, clean cut.
Color, pale, muddy, ashy, unlustrous, not
fresh, not bright, not ruddy.
4 THE MORPHOLOGY OF THE BLOOD.
Holding firmly the coloring matter, yet soft
and plastic.
High colored, smooth and even in outline,
hard and rigid.
Allowing the coloring matter to escape freely,
obscuring their outlines.
Mammillated.
Cholesterine in.
2. The Colorless Corpuscles.
In normal proportion.
In too small quantity.
In excess.
Normal in quantity or in excess ; sticky and
plastic, endangering the formation of thrombi
and emboli.
Ragged and broken down.
In excess, ragged and broken.
In excess, smooth and even.
Containing vacuoles.
Containing vegetations that distend them to
an enormous size.
Contain thin, bladder-like, empty cells, of
various sizes, that distend them.
Contain the spores of crypta syphilitica.
3. The Serum.
Too little.
Too much.
THE MORPHOLOGY OF THE BLOOD. 5
Normal.
Its fibrin :
In normal proportion.
In too small proportion.
In too large proportion.
Meshes normal in size and in arrange-
ment, allowing the free circulation of
blood-cells through them.
Meshes too small to admit of the free
circulation of blood -cells through
them, on account of which the blood-
cells arrange themselves in ropy
rows, or ridges and masses, being
held in the meshes of the partially
clotted or contracted fibrin. In such
cases, the individual fibrin filaments
have an increased diameter and opa-
city.
Want of, in pernicious anaemia.
Enlarged, thickened, and more opaque
in rheumatism.
Thrombi of, filled or not with granular
or crystalline matters.
Sticky and plastic.
Minute grains and ragged masses of black,
blue, brown, or yellow pigment.
Fat, globules and masses of.
Amyloid matters.
Broken-down parent cells.
Thrombi of algae spores.
Thrombi of algae filaments.
6 THE MORPHOLOGY OF THE BLOOD.
Algae filaments and spores without aggrega-
tion.
Fungi spores.
Fungi filaments.
Zymotosis regularis spores.
Zymotosis regularis mycelial filaments.
Entophyticus haematicus spores and fila-
ments.
Penicillium quadrifidum spores and mycelial
filaments.
Penicillium botrytis infestans.
Crypta syphilitica spores and filaments.
Mycoderma aceti spores and filaments.
Saccharomyces cerevisiae.
Alcohol and acid yeasts.
Microsporon furfur.
Gemiasma, alba, plumba, rubra.
Mucor malignans.
Biolysis typhoides.
Crypta carbunculata.
Ios variolosa vacciola.
Ios vacciola.
Cryptococcus Xanthogenicus (Freire).
Cystine, granules and crystals.
Phosphates, granules and crystals.
Stelline, granules and crystals.
Stellurine, granules and crystals.
Granules and crystals of a miscellaneous
character.
Conchoidine.
THE MORPHOLOGY OF THE BLOOD. J
Pigmentine, black, brown, bronze, aniline
blue, red, yellow, etc.
Cholesterin.
Leucin.
Creatin.
Uric acid and urates.
Carbonate of lime.
Inosite.
B. MORPHOLOGY OF THE BLOOD IN HEALTH.
According to Conventional Nomenclature to
Aid in Studies.
Blood from Capillaries :
Color ; bright, fresh, clear, ruddy, strong.
Clotting ; rapid and firm.
Red corpuscles — arrange themselves in num-
mulations, or are scattered evenly over the
field. Normal in size. Non-adhesive. Cen-
tral depression well marked on both sides ;
periphery well rounded, clean cut. Hold col-
oring matter firmly. Pass readily to and fro
through the fibrin filaments. Appear fresh
and fair, giving an appearance of health, like a
rosy-cheeked maiden full of life.
White corpuscles — normal in size. Not en-
larged by internal collections of foreign bodies.
Amoeboid movements strong or not Propor-
8 THE MORPHOLOGY OF THE BLOOD.
tion, one to three hundred of red corpuscles.
Consistence good. Not sticky. Color a clean
white. Freely moving at will.
Serum — clear and free at first sight from any
form. After five minutes, most delicate semi-
transparent fibrin filaments appear, forming a
very light network in the field, which offers no
obstacle to the passage of the corpuscles.
There should be no spores nor vegetations
in healthy serum, though they may be found
by very minute examination, or by letting the
blood stand for several days in closely stopped
phials at a temperature of from 60-750 Fahren-
heit. This is not saying that spores and fila-
ments cannot be found in blood of persons
calling themselves healthy — for some diseases
exist in a latent condition, like rheumatism,
syphilis, cystinaemia, and consumption. I have
met with people who, on finding vegetations in
their blood, have decided not to accept the evi-
dence because they deemed themselves healthy.
Again, it is difficult to find a perfectly healthy
person in the community ; this was made pub-
lic during the "late unpleasantness," when
drafts were made for soldiers. The blood evi-
dence must be taken in connection with that of
the other physical signs.
THE MORPHOLOGY OF THE BLOOD. 9
'C. MOVEMENTS AND CHANGES OF THE BLOOD
IN DYING.
These are important and need study. They
are like the behavior and manners of people
that convey ideas, as they are to be gained in
no other way. After one has learnt these
movements in health, he will appreciate them
in disease. Again, as Dr. Salisbury remarks,
there are tendencies to diseased states in the
blood which need detection, as they are much
easier remedied than when confirmed. It is
impossible to convey these ideas on paper or in
drawings ; they must be learned from actual
observation. The morphology of healthy blood
is a most rigid test, and in delicacy and far
reaching goes beyond any of the other physical
signs. When generally known and appreci-
ated, it will be of great benefit, specially in life
insurance examinations, army or navy examin-
ations, and in the study of the best modes of
physical culture.
D. MORPHOLOGY OF THE BLOOD IN CONSUMP-
TION OF THE LUNGS.
Use. — In diagnosis, exceeding in value aus-
cultation and percussion, because it detects
consumption of the lungs before there is any
lesion of them. To show the real progress of
the case by the substitution of the morphology
IO THE MORPHOLOGY OF THE BLOOD.
of health more or less, to show when patients
have lapsed in the treatment by eating for-
bidden food, and to show wThen there is a real
cure. To repeat, most valuable of all to make
out a diagnosis of consumption with as much
certainty as it is possible in human affairs, and
by removing the uncertainty, sometimes dread-
ful, of the diagnosis that accompanies the con-
ventional first stages of consumption of the
lungs.
This value is so great that it is more than a
warrant for this publication to be made. It is
hardly possible to overestimate the importance
of this department of physical exploration.
First or Incubative Stage.
Red blood-corpuscles are less in number,,
ropy, and sticky, more or less, but not much
changed otherwise.
Second Stage, of Transmission.
i. Red corpuscles. — Color pale, non-lustrous;
not clear cut, not ruddy. Consistence, sticky,
adhesive. Coating of neurine removed. Not
so numerous as in normal blood. Owing to
the increased size and strength of the fibrin
and the stickiness, they form in ridges, rows,
but not so marked as in rheumatic blood.
They accumulate in aggregations of confused
THE MORPHOLOGY OF THE BLOOD. I 1
masses, like droves of frightened sheep. They
adhere to each other, and are rotten, as it were,
in texture.
2. White corpuscles. — Enlarged and dis-
tended by the mycoderma aceti, or spores of
vinegar yeast, that are transmitted into the blood
stream from the intestines.
3. Serum. — More or less filled with the
spores of mycoderma aceti or vinegar yeast.
These occur either singly or in masses of
spores, which is the common form in which
they are found, wherever vinegar is produced.
The fibrin filaments are larger, stronger, more
massive than in health, and form under the
microscope a thick network which is larger,
stronger, and more marked in direct proportion
to the severity of the disease or the amount of
accumulation.
Besides, the serum is apt to be of a dirty ash
color.
The sticky white corpuscles, the massive
fibrin filaments in skeins, and the yeast spores
alone or combined, form aggregations, masses,
collects, thrombi and emboli which block up the
blood-vessels of the lungs soonest, because
exposed to cold air, the most of any viscus ;
the blood-vessels contract, and thus arrest the
thrombi and form a heterologous deposit, which
is called tubercle.
12 THE MORPHOLOGY OF THE BLOOD.
The Third Stage, or Stage of Tubercular
Deposit.
These deposits increase so long as vitality
subsists in the tubercle and surroundings.
When vitality ceases, the tubercle softens or
breaks down. Sometimes, if the process is
very slow and life slightly inheres in it, the
proximate tissue undergoes fatty infiltration,
which preserves it from readily breaking down.
The morphology of the blood is the same for
the second and third stages of consumption.
Fourtli Stage.
Interstitial Death.
Morphology of the blood in this stage is the
same as in the second and third, save that it
becomes more impoverished.
The red corpuscles are thinner, paler, much
lessened in number, increased in adhesiveness,
stickiness, and poverty. Devoid more or less
of neurine.
The white corpuscles are fewer in number,
more enlarged ; often ragged and rough. Dis-
tended with spores of mycoderma aceti, more
adhesive, and sticky.
The serum. — Fibrin filaments are thickened,
stronger, more massive, and more skeins of
them present. The collects of mycoderma
THE MORPHOLOGY OF THE BLOOD. 1 3
aceti are very much larger and more numer-
ous ; in moribund cases, I have seen them so
large as almost to fill the field of the microscope.
They present anfractuous edges and amoeboid
prolongations, giving them a weird, bizarre
aspect which, under the circumstances, have a
portentous aspect, for the larger and more
numerous the spore collects of mycodermi aceti
are, the more dangerous the case.
One great proof of the so-called Salisbury
plans is, that they will entirely change the mor-
phology of consumptive blood to that of health,
and the whole process can be watched and
studied to the delight of all concerned.
E. MORPHOLOGY OF THE BLOOD IN
RHEUMATISM.
Rheumatism may be called the
Gravel of the Blood.
Color varies from that of health to the pale-
ness of anaemia.
Consistency and rapidity of clotting increased.
1. Red corpuscles. — Color usually impaired,
not always ; coloring matter not so firmly held
as in health.
Adhesive, sticky, often drawn out into elon-
gated lozenge-shaped bodies with pointed ends,
and sometimes filamentous joining with one or
more of their fellows.
14 THE MORPHOLOGY OF THE BLOOD.
Clot in winrows. ridges, and huddled masses;
sometimes quite formless. This is caused by
the massive fibrin filaments holding them fast,
as it were, in their firm meshes. The same
thing is seen in consumptive blood, but to a
less degree.
2. White corpuscles usually enlarged ; adhe-
sive, sticking to each other and to the red
corpuscles, and matters found in the serum.
Indeed, it seems to be the office of the white
corpuscles so far as possible to swallow and
envelop any foreign substance that may find its
way into the blood. Thus we find crystalline
matters in the white blood-corpuscles in rheu-
matism, though not always.
They undergo amoeboid movements as in
healthy blood — they have independent locomo-
tion. Disease does not seem to impair their
automatic movements.
Often they are increased in number. If there
is fatty degeneration going on, they will be
found to contain fat in globules.
3. The serum.
Fibrin filaments — in massive, strong and
sticky threads, in abundance — in meshes, which
are finer than in health, visible plainly — strong
and hold the red corpuscles like prisoners — in
skeins, like tangled skeins of silk — in masses
forming thrombi which, when fastened, form
emboli.
These thrombi are apt to involve and em-
THE MORPHOLOGY- OF THE BLOOD. 15
brace white and red corpuscles and crystalline
bodies to be named below. Sometimes the
fibrin filaments are found in large round strings,
curled up fancifully by the motion of the blood
stream, and looking like the mycelial filaments
of vegetations, from which they can be distin-
guished by an absence of entire cylindrical
outline — ragged broken edges here and there
and dichotomous and polychotomous divisions
of the trunk, different from vegetations of
syphilis for example. It is the presence of
these fibrin filaments that makes the blood ropy,
adhesive, and sticky. They have the tendency
to block up the blood stream and besides to be
locally deposited in the tissues, specially when
the circulation is sluggish, as near the extremi-
ties and the joints.
Crystalline bodies, or gravel of the blood.
These are numerous and readily recognized ;
some of them are as follows : —
1. Uric acid and urates of soda.
2. Phosphates — specially the triple phos-
phates of lime and soda.
3. Oxalate of lime.
4. Cystine. This is quite common and easily
detected.
5. Carbonate of lime, rare.
6. Stelline and stellurine. These occur
mostly in granular form in the serum, but in
I'b THE MORPHOLOGY OF THE BLOOD.
old cases, where the system is saturated, they-
are crystalline.
7. Black, brown, aniline blue, bronze, orange,
red and yellow pigments in the form of flakes
or small masses are common in rheumatic
blood, and may be termed gravelly matters,
that should have been eliminated by the kid-
neys or bowels or skin.
Latent Condition of the Characteristics of
Rheumatic Blood.
The morphology of rheumatic blood exists
in a latent condition in persons apparently
well ; but when they are exposed to cold, the
blood-vessels contract, catch and detain these
abnormal elements, and we have a stasis of the
blood which may be active or passive and
manifests itself in heat, fever, pain, swelling,
inflammation or passive congestion, effusion,
etc., and which make up what is known as an
" attack of rheumatism." The fever may re-
sult from the effects of nature to get rid of the
intruders, just as a householder will become
hot in expelling from his premises a thief who
is difficult to get rid of. Or to use another
simile, the attack of rheumatism is like the ex-
plosion of a gun. The charge in the gun is
the morphology of rheumatic blood, and the
cold is the pulling of the trigger. The charge
may be latent in the gun for years, but it is
THE MORPHOLOGY OF THE BLOOD. IJ
there with its potential energy ready to be-
come actual from an exciting cause.
F. FIBR^EMIA.
In a nomenclature which wras made before
the present advance of knowledge, there is dif-
ficulty in making it fit to the new era. I shall
not attempt to relieve this difficulty, but try to
adapt the subject to the conventional names,
as the object of this work is practical aid in
treating diseases, no matter what they are
called.
Fibrmnia is where the fibrin is in excess in
filaments, skeins, curled massive fibres like
strings — thrombi and emboli. These are in
a more exaggerated condition and form than in
consumption or rheumatism, and are not
necessarily associated with the crystalline
matters or gravel. Sometimes the fibres look
like a scalp that has been taken from the head
of a woman with long tresses of hair.
G. THROMBOSIS
Is where masses of fibrin accrete and con-
solidate together, including or not the red
corpuscles, white corpuscles, crystalline and
pigmentary bodies, spores and mycelial fila-
ments or vegetations, one or all.
1 8 THE MORPHOLOGY OF THE BLOOD.
H. EMBOLISM
Is where a thrombus has been caught or en-
gaged in a blood-vessel and acts as a plug
disturbing the circulation. When the embolus
is made up of spores of mycoderma aceti or
vinegar yeast and is caught in the lungs, it de-
velops tubercle of the lungs, and so in other
parts of the body. So senile gangrene of the
extremities is caused by fibrinous clots plug-
ging up an artery.
I. PRE-EMBOLIC STATE.
As thrombi precede emboli, so they can be
detected in the blood before the embolism, sim-
ply by the morphology of the blood. In this
way, sudden deaths from embolism, specially
in the puerperal state, can be averted, and this
aid alone renders the microscope an invaluable
assistant to the physician who is devoted to his
profession, and is sufficient to redeem it from
the title of " accursed," as given it lately by a
divine of this city.
j. ANAEMIA
Is where the serum is in excess and the red
and white corpuscles are in diminution; fibrin
also in excess.
THE MORPHOLOGY OF THE BLOOD. 19
K. PERNICIOUS ANAEMIA
Is where the red corpuscles are not formed or
normally replaced. Here the blood glands are
at fault, from improper alimentation. It is es-
sentially a food disease.
L. MORPHOLOGY OF THE BLOOD IN SYPHILIS.
This morphology can be found associated
with any of the preceding morphologies, but,
when present by itself, it is recognized in the
Serum in two forms.
First. The spores of the crypta syphilitica.
Second. The mycelial filaments or full de-
velopment of the same. The fructification is
yet to be seen.
1. The spores are very minute, automobile,
very lively, active, and saltatory. Carefully
focussed a little off, they show a copper color.
They dance about in the serum spaces and
over the red corpuscles, where they elude
search, unless one is a good and careful ob-
server. They also crowd or are crowded into
the white corpuscles, in which their color ap-
pears to greater distinctness, and which cor-
puscles are often distended to a great size.
2. The mycelial filaments of the crypta syph-
ilitica are round, cylindrical, slightly tapering,
mostly in small curved pieces broken off, with
20 THE MORPHOLOGY OF THE BLOOD.
one end larger than the other, or clavate at one
end.
Color, when a little out of focus, copper.
Sometimes they are long and wavy, sometimes
branching. They are found in best condition
in the walls of chancres.
The great value of a diagnosis of the mor-
phology of syphilitic blood lies in the almost
instant detection of the disease without a word
to the patient, and in telling at once when the
disease is cured, for it is not cured unless the
blood is free from the plant.
The use of this morphology would prevent
the terrible lesions of tertiary syphilis, as the
patient would not be allowed to run into this
stage. It tells at once the real progress of the
case under treatment, and shows how remedies
act, or if they are good for anything. It
amazes the writer to see how indifferent the
profession are to the morphology of syphilitic
blood. It is an " idle tale," just as ocean steam
navigation, telephony, and railroading were.
Ere I die, I hope to see the world enjoying the
benefit of this use of the microscope, as it does
the once " idle tales " named.
M. MORPHOLOGY OF THE BLOOD IN ECZEMA.
Here the spores are black and still, not auto-
mobile, but passive. Parent vegetation not
made out. This morphology may be found
THE MORPHOLOGY OF THE BLOOD. 2 1
associated with any of the others. No case of
eczema is cured unless these spores are elimi-
nated.
N. MORPHOLOGY OF THE BLOOD IN SCROFULA.
This is either syphilitic or tuberculous, or
both. See the morphologies of consumption
and syphilis.
O. MORPHOLOGY OF THE BLOOD IN MALARIA.
Here the diagnosis rests on the forms found
in the serum. There are :
i. The spores of the gemiasma plants or
other plants found in malarious districts, which
rise in the air from the soil, and are inhaled
into the air passages where the blood comes
within one-thfee-thousandth (^) of an inch of
the atmosphere. They there gain admission to
the blood.
2. The sporangias of the mature gemiasmas.
These are pale or white in color, and gen-
erally contain less spores than normal, as would
be expected in algae growing in an unnatural
habitat, as the inside of the human body.
Remarks. — i. Are most common. 2. Are
rare, but in doubtful cases, if the skin mor-
phology of the axillae is studied, the full-grown
aerial form of the gemiasmas may be found
there for corroborative diagnosis. The malaria
2 2 THE MORPHOLOGY OF THE BLOOD.
blood morphology may exist in a latent con-
dition in persons apparently healthy, needing
a torpid liver or a cold to make their energy
actual, just as in the case of the loaded gun
alluded to above.
There are several kinds of cryptogamic
vegetations that cause malaria. Some of these
are innocent vegetations in their natural habi-
tat, but when animalized by coming in contact
with animal matter in decay, and living on it,
then they are endowed with a power to attack
and live on the human habitat, and become the
predisposing cause of malaria — so termed prob-
ably because these causative vegetations invade
through the air — when taken into the digestive
organs, as they must be in quantities, they
seem to be destroyed by the juices of the ali-
mentary canal. See "Malaria," McNaughton
prize essay, 1882, by J. H. Salisbury, M.D.,
LL.D. New York: W. A. Kellogg, 1885.
P. HEREDITARY TAINTS
Are conventionally supposed to come through
the blood, but the evidence of blood morpholo-
gies does not bear out this idea in a general
way. Consumption comes by feeding on food
that undergoes alcoholic and vinegary fermenta-
tion in the digestive organs.
The spores of crypta syphilitica and eczema
may be transmitted from the mother or father
THE MORPHOLOGY OF THE BLOOD. 23
to the offspring, but they are now about the
only ones that can be traced.
Q. CANCER
Is more a disease of nutrition — tissue devel-
oped under mob law — and goes in families,
because families feed on the same food at the
same table. The researches of Dr. Domingos
Freire, of Rio Janeiro, and others point out a
microbe. This is an advance in our knowledge,
for hitherto we have been able to detect no
vegetation in cancerous blood before the gen-
eral system has been broken down in the last
stages, and here it seems more a result than a
cause. But we are grateful for any more light,
and accord Dr. Freire all credit and honor for
his work.
R. MORPHOLOGY OF THE BLOOD OF VARIOLA
AND VACCINIA.
Ios variolosa vacciola spores and filaments
in variola.
Ios vacciola spores and filaments in vaccinia.
S. MORPHOLOGY OF THE BLOOD IN TYPHOID
FEVER.
Biolysis typhoides spores and filaments.
The spores grow with great profusion in the
24 THE MORPHOLOGY OF THE BLOOD.
white blood-corpuscles, leaving them as empty
sacs sometimes floating in the blood stream.
The spores also grow in profusion in all the
epithelia of the body. Patient not cured before
the plant is removed.
T. MORPHOLOGY OF THE BLOOD IN SCARLET
FEVER AND DIPHTHERIA.
Scarlet fever. — Mucor malignans spores, or
a species very near kin to it
Diphtheria. — Mucor malignans.
The aerial form may be cultivated from the
throat membranes, but it is very dangerous
work. The writer found that a three and a
half years' sojourn of the diphtheritic membrane
(from the uvula of his daughter Mary who died
in spite of all that was done) in strongest car-
bolic acid was not enough to destroy the
life of the vegetation. He confesses he was
frightened, and abandoned the study of this
particular spore.
U. MORPHOLOGY OF BLOOD IN FATTY
DEGENERATION.
The white corpuscles contain globules of fat
more or less abundant. The serum in advanced
cases, or cases tending that way, contains fat
globules more or less large and numerous.
The red corpuscles are apt to have not full
THE MORPHOLOGY OF THE BLOOD. 25
color, strength of outline, and be adhesive, pale,
sticky.
Remarks. — The fibre of an outlying muscle
may be brought out by a minute spear thrust
in and tested for fat in the fibrillae (S.), as a
confirmation of the diagnosis. Very important
in the treatment of softening of the brain, apo-
plexy, Bright's disease, etc.
V. THE MORPHOLOGY OF THE BLOOD IN
FIBROUS CONSUMPTION.
Here the mycoderma aceti or vinegar yeast
does not get into the blood, and change it, as
in tubercular consumption, since the pylorus
keeps the vinegar yeast in the stomach. There
is breaking down of living tissue to a less ex-
tent. This tissue has been thickened, hardened,
and made stony from deposit of gravel. The
diagnosis is not so easy as that of tubercular
consumption.
W. CHOLESTER^MIA.
Red blood-discs soft, yielding, plastic, often
sticky, holding feebly the coloring matter which
escapes and obscures the field.
Serum contains cholesterin.
Diagnosis. — Blood standing a few hours on
the slide ; crystals of cholesterin appear on the
edges of the slide.
26 THE MORPHOLOGY OF THE BLOOD.
This shows a tendency to amyloid disease in
the spleen, lacteal and lymphatic glands, liver,
kidneys, heart and large blood-vessels, and
amyloid matters are found in the blood stream.
X. MORPHOLOGY OF THE BLOOD IN CAR-
BUNCLES.
Crypta carbunculata spores and filaments
which are found in abundance also in the
sloughs of the carbuncle.
Y. THE MORPHOLOGY OF THE BLOOD IN
YELLOW FEVER.
Cryptococcus xanthogenicus (Freire). See
his monumental work.
Z. LEUCOCYTH/EMIA
Is where the white corpuscles are in large ex-
cess and the red corpuscles in diminution ; se-
rum in excess.
II.
MORPHOLOGY OF SPUTUM.
MODE OF STUDY.
One and one-fifth inch objective ; one inch
ocular.
Polarized light needed sometimes to distin-
guish the fibres of lung tissues from other
organic fibres.
At least three specimens should be collected
and studied at each examination. Sputum
may be sent from patients prepared as follows :
dry, away from sun or stove, a mass of morning
sputum about one inch in diameter on white
writing paper. The specimen will keep indefi-
nitely and may be mailed anywhere. When
ready for examination, soak specimen with a
little water. The objectives made by the late
Mr. Tolles and by his successor, Mr. John Green,
will focus through a slide. It is therefore much
easier to place some of the moistened sputum
on a slide and then cover with another slide ;
this is done quicker than when one has to use
thin covers. It is a pity that other American
objective makers cannot follow the example of
28 MORPHOLOGY OF SPUTUM.
the illustrious Tolles, and make one-fifth inch
objectives that will focus an eighth of an inch
from the object, and not a sixteenth or thirty-
second, as the common rule is.
Sputum needs morphological study as much
as urine or blood.
As the morphology may include that of the
air, of course this is incomplete.
Aerial forms of yeasts.
Albuminoid matters.
Alcoholic and lactic acid yeasts.
Algae, names unknown.
Amorphous organic and inorganic matters,
including dust and dirt inhaled from the atmo-
sphere.
Amyloid bodies.
Anabaina irregularis.
Any of the microscopic fauna and flora found
in drinking waters.
Asthmatos ciliaris.
Bacilli.
Bacteria, so-called.
Blood-corpuscles, white and red.
Butter.
Calculi made up of :
Cholesterin.
Cystin.
Oxalate of lime.
Phosphate of lime.
Triple phosphates.
Uric acid.
MORPHOLOGY OF SPUTUM. 29
These may all come under the appellation of
" gravel of the lungs."
Carbon, from smoke inhaled.
Carbonized tissue from lungs.
Cells and fibres of lung tissue.
Cholesterin.
Clots of blood.
Colloid.
Connective animal tissues.
Contents of giant cells escaped outside of
walls.
Cotton fibre.
Cream of tartar crystals.
Crystals with two or more terminals.
Cystin.
Dust and dirt.
Elastic lung fibres.
Elements of animal food eaten, cooked and
uncooked.
Elements of vegetable food eaten, cooked
and uncooked.
Epithelia, ciliate, non-ciliate, pavement, col-
umnar.
Fat.
Feathers.
Foreign substances inhaled,
Fucidium.
Fusiform crystals.
Gemiasma alba.
Gemiasma rubra.
Gemiasma verdans.
30 MORPHOLOGY OF SPUTUM.
Granular tubercular masses.
Granular tuberculous matter, so-called,
sometimes fetid in odor.
Gravel, crystalline.
Gravel, granular.
Gravel, massive.
Hairs of plants and animals.
Inelastic lung fibres.
Ipecac dust.
Lactic acid alcoholic yeast.
Lactic acid mother of vinegar.
Lactic acid vinegar yeast.
Leptothrix buccalis spores and filaments.
Leptothrix buccalis heavily loading and
enormously distending lingual papillae with
spores and filaments.
Leptothrix buccalis in epithelia.
Linen fibre.
Lumina of blood-vessels.
Micrococcus spores.
Microsporon furfur.
Mucor malignans (diphtheria).
Mucous cells swarming with the moving
spores, probably of the leptothrix buccalis ;
not found in the mouths of healthy infants.
Mucous corpuscles.
Mucous corpuscles, caudate and deformed.
Mucous corpuscles distended with albumin-
oids.
Mucous corpuscles distended with crystalline
and other bodies.
MORPHOLOGY OF SPUTUM. 3 1
Mucous corpuscles distended witn cystin or
giant cells.
Mucous corpuscles distended with leptothrix.
Mucous corpuscles distended with melanotic
matters.
Mucous corpuscles distended with oxalate of
lime.
Mucous corpuscles distended with triple
phosphates.
Mucous corpuscles distended with uric acid
and urates.
Mucous corpuscles, normal.
Mucous filaments and fibres.
Mucus ; normal and ropy and viscid (colloid).
Muscular fibres of food.
Mycelial filaments of acetic acid vinegar, and
lactic acid vinegar yeasts.
Mycelial filament of fully developed yeasts
and other fungi.
Mycoderma aceti, spores and filaments.
Other crystals whose names have not been
made out.
Oxalate of lime.
Papillae of tongue, usually infiltrated with
spores of leptothrix.
Partially carbonized vegetable tissues from
smoke.
Phosphate of lime.
Pigment matters.
Pitted ducts, etc.
Portions of feathers of animals and insects.
32 MORPHOLOGY OF SPUTUM.
Potato starch.
Pus-corpuscles.
Sarcina.
Silk fibre.
Skeins of mycelial filaments.
Special pollens.
Spirilina splendens (asthma), Salisbury, 1865.
Spirillum.
Spores of artemisia absinthium.
Starch, corn.
Starch, potato.
Starch, wheat.
Swarms of spores.
The whole lumen of a vein just before end-
ing in the capillary.
Tough, ropy mucus.
Triple phosphates.
Tubercles.
Uric acid and urates.
Uric acid crystals.
Vegetable tissues.
Vegetations found in croupal membranes
(Cutter, 1879).
Vibriones.
Vinegar yeast.
Vinegar yeast and lactic acid vinegar yeast
Wheat starch.
Woody fibres.
Yeast plants.
Yeast sporangia, alcoholic and lactic acid.
III.
MORPHOLOGY OF FECES.
SHOWS THE CONDITION OF DIGESTION,
GOOD, BAD, OR INDIFFERENT, AND SOME
PATHOLOGICAL STATES.
MODE OF STUDY.
Prepare specimens for mailing, in the same
way as sputum. A good microscope, one inch,
one-fifth inch objectives, one inch ocular, po-
larized light.
Moisten specimen, and place on slide, and
(if the physician has a fifth-inch objective that
will focus through a common slide) cover spe-
cimen with a piece of slide. This is quicker,
easier, cleaner, and more effective than with
thin covers.
Acetic acid yeasts.
Alcohol.
Another species of sarcina.
Bacteria.
Beard of wheat. ~^
Beef-red pieces of thickened mucus.
Black pigment from glands of Lieberkuhn
and Brunner.
34 MORPHOLOGY OF FECES.
Blood.
Butyric acid yeasts.
Carbonate of lime.
Casts of intestinal glands.
Cholesterin.
Colloid.
Colloid matters, resembling ovarian, thyroid,
and mammary tumors and those of testes.
Cotton fibre.
Cream-colored pus.
Crystals of phosphates, cystin, urates, oxal-
ates, etc., colored with melanotic matters.
Crystals of sugar.
Crystals of triple phosphates.
Crystals of cystin.
Crystals, urates, uric acid, etc.
Different vegetable fibres.
Eggs of ascarides.
Eggs of different worms.
Eggs of taenia.
Eggs of trichocephalus dispar.
Epithelium.
Fat with acicular crystals.
Fat globules.
Gelatinous mucus.
Gluten.
Granular, amorphous, homogeneous matter,
normal feces, with triple phosphates.
Healthy feces are homogeneous, formless,
like a solid extract.
Homogeneous fecal matter.
MORPHOLOGY OF FECES. 35
Lactic acid yeasts.
Linen fibre.
Microcystis and plants allied to them, un-
named.
Mucous corpuscles.
Muscular fibre.
Mycoderma aceti.
Oil globules.
Oils.
Oxalate of lime.
Partially cooked and burnt muscular fibres.
Penicillium.
Pigmentine, black, etc.
Remains of animal tissues:
Connective tissue.
Striated fibres: striae non-, partially or wholly
effaced by digestion, etc., etc.
Remains of vegetable tissues :
Apples : — Clear, almost transparent sacs of
thin cellulose.
Baked beans : — Sacs of thick cellulose con-
taining starch cells ; when un- or partially
cooked, they are globular, pyriform, elongated,
compressed, apparently triangular, sometimes
reminding of dififlugia cratera, sometimes of
pelomyxae, and so on ; the transparent enve-
lope of cellulose looks like the clear margin of
gemiasma verdans, rubra, and plumba found
in malaria. The thickness of this coat is about
one-seventeenth of the diameter of the sac.
The starch cells polarize light or not as th.ey
36 MORPHOLOGY OF FECES.
are uncooked or cooked. The cellulose enve-
lope of the entire bean is made up of layers of
crystal-like shapes, which are set in rows, their
internal and external faces appearing very
much like the tops of the Giant's Causeway
crystals of traprock. These crystal-like ele-
ments of cellulose, when un- or partially
cooked, are but slightly hourglass-shaped,
but, when thoroughly cooked, appear like dou-
ble-headed tacks.
Epithelial cells and areolar tissue of beans
may also be present.
Bananas : — Clustered masses of starch grains.
Cranberries : — Pigment cells of skins.
Greens : — Spiral ducts in bundles, etc.
Potatoes : — Cork cells, starch cells, areolar
tissue. Gubernaculum tissues that lead from
the eyes to the centre. The starch bundles or
the starch in homogeneous masses, the pitted
ducts, the vascular bundles, etc.
Wheat: beard, outer coats, gluten cells, are-
olar tissue, etc., etc.
This is only a very partial list of vegetable
tissues. I have only indicated a few elements
in order to show how to go at the study, for
my own work has led me to distinguish many
more forms.
Saccharomyces cerevisiae.
Sarcina ventriculi.
Seroline.
Several species of minute algae.
MORPHOLOGY OF FECES. 2)7
Shreds of coagulated mucus.
Sirocoleum.
Strings of thin folded laminae of coagulated
mucus.
Strips of tissues, scourings.
Sugar.
Sulphuretted hydrogen vegetations.
Tarry condition from bile which should have
been carried out by urinary organs and sweat
glands (Salisbury).
Tegument of wheat, cigar coat.
Tough ropy mucus (colloid).
Triple phosphates.
Tubercles.
Urates.
Vegetations of putrefactive decomposition.
Vinegar.
White coagulated mucus, like folded tissue
paper.
White connective fibrous tissues.
Yeast plants.
Yeasts :
Acetic acid.
Alcoholic.
Butyric acid.
Lactic acid.
IV.
MORPHOLOGY OF THE SKIN.
MODE OF STUDY.
Simply moisten the skin with distilled water
and rub in with a clean knife blade. Then
scrape off and place under microscope ; use
one-fifth inch or one-tenth inch objectives or
higher as needed, having water enough to
make a thin clear field ; in studying dirt and
some of the grosser forms, use lower powers.
Acarus autumnalis.
Acarus folliculorum, steatozoon folliculorum.
Acarus scabeii.
Acne.
Adenoid.
Ague plants. Among these gemiasma alba,
gemiasma plumba, gemiasma rubra.
Anabaina subtularia.
Animal hairs.
Anthrax vegetations.
Asthmatos ciliaris.
Bacteria.
Blood, free and dried.
Blue, purple, black pigments.
Boils, vegetation of.
MORPHOLOGY OF THE SKIN. 39
Bots.
Cancer.
Carbonate of lime.
Carbuncle, anthrax.
Carpet fibres.
Chloasma.
Cholesterin.
Cimex lectularius.
Crypta syphilitica (Salisbury) spores and
filaments.
Cystin.
Dermatophyton.
Dirt.
Drugs, ipecac, etc.
Eczema spores.
Eggs and larvae of insects.
Eggs of tape-worm.
Epithelia, normal.
Epithelia, lactic acid yeast in.
Epithelia, vinegar yeast in.
Epithelia with biolysis typhoides.
Epithelioma.
Erysipelas vegetations.
Fat.
Fatty degeneration.
Fatty infiltration of muscles.
Favus, tinea favosa.
Feathers.
Fibres of textile products, cotton, linen, wool.
Fibroid tissues.
Filaria medinensis.
40 MORPHOLOGY OF THE SKIN.
Floor fibres.
Flour and flour vegetation, as on baker's
wrists.
Fungi.
Fungoid spores and mycelia of unnamed
plants.
Germs in epithelial and mucous tissues,
glands and follicles of eye and other organs.
Gravel, foreign and native.
Hairs and vegetations.
Jiggers.
Jute.
Keloid.
Kerion.
Lard.
Leather.
Leprosy spores.
Lice.
Malignant pustule vegetations.
Measles vegetations.
Mentagrophyton.
Microsporon Audouini.
Microsporon furfur.
Mosquitoes, parts of.
Mucor malignans of scarlet fever and diph-
theria.
Mucus.
Mycetoma, Chionyphe Carteri.
Mycoderma aceti spores and filaments.
Nails, vegetations and dirt under.
Oils
MORPHOLOGY OF THE SKIN,
41
Onychomycosis, onychia parasitica.
Oxide of lime.
Paint lead salts.
Pediculus capitis.
Pediculus corporis vel vestimenti.
Pediculus pubis.
Phosphates of lime.
Pigment matters.
Plant hairs.
Poisonous plant products.
Pollen of plants.
Porrigo scutulata or tinea tonsurans.
Protococcus monetarius under ends of finger
nails.
Pulex or sarcopsylla penetrans, Chigoe.
Pus.
Pus decomposing into fat.
Saccharomyces cerevisiae.
Salt, chloride of sodium.
Scald head.
Scarlet fever vegetations, mucor malignans.
Scars of pregnancy and fat distention.
Seborrhoea.
Secretions of hair and sweat glands.
Serum.
Silica.
Silk.
Small-pox vegetations.
Soap.
Spermatozoa.
Stains of silver, etc.
42 MORPHOLOGY OF THE SKIN.
Starch grains of all kinds.
Steatozoon folliculorum.
Stellin.
Stellurin.
Sulphate of lime.
Sweat.
Syphilodermata.
The objects found in the morphology of the
air are to be expected in the morphology of
the skin.
Tinea circinata, trichophyton tonsurans.
Tinea decalvans, microsporon Audouini.
Tinea favosa, achorion Schonleinii.
Tinea kerion.
Tinea sycosis, microsporon mentagraphytes.
Tinea tarsi, tricophyton.
Tinea tonsurans, tricophyton.
Tinea versicolor, microsporon furfur.
Trichosis caninus (Salisbury).
Trichosis felinus (Salisbury).
Triple phosphates.
Uric acid.
Vaccinia vegetations.
Variola vegetations.
Vegetations from water used in washing.
Vegetations of animal poisons.
Vibriones.
Woody fibre.
Yeasts growing in epithelia of skin.
Zinc, oxide of.
V.
MORPHOLOGY OF THE URINE.
It is good to use an inch objective as well as
a fifth (1-5) inch objective in studying the
morphology of the urine. The one-inch objec-
tive at once brings out the casts of kidney
tubes, prostate gland ducts, spermatic ducts,
besides the colloid matters that otherwise elude
search and are, in my opinion, very important
clinically.
Urinoscopy is more valuable than the pulse
in telling the status of the liver, stomach, kid-
neys, urinary organs, and general systemic
condition. It should be used daily. The urine
voided on rising in the morning is the best to
examine. The chemical examination of the
urine should go side by side with the mor-
phology ; neither supersedes the other.
The aim should be to make each patient's
urine come up to the standard of the urine of
a healthy infant, nursing a healthy mother's
breast. This urine is clear, odorless, and free
from deposit. The cures in the so-called Salis-
bury plans include an aiming at a conform-
ity to this standard. It is a mistake for each
44 MORPHOLOGY OF THE URINE.
physician not to make his own examina-
tions of urine almost daily. The urine is very
sensitive to bad feeding and overdoing in any
way, and shows them almost as plainly as if it
said "bad feeding and overdoing" in so many
words. Lastly, many physicians will not ex-
amine urine chemically or microscopically, as
such examinations appear to be too difficult,
though these men may be masters in the prac-
tice of medicine ; there is nothing in the present
knowledge of the urine that any one of moder-
ate ability may not and should not master, for,
to repeat, the urine is a source of valuable
clinical information.
Accidental foreign bodies.
Acicular crystals, same as found in ague soils.
Ague plants, mostly in embryonic forms,
sometimes mature.
Amorphous urates.
Amyloid matter, common,
Anabaina irregularis.
Arachnida.
Asthmatos ciliaris (rare).
Bacilli.
Bacteria.
Blood, red corpuscles.
Blood, white corpuscles.
Calculi of urates and phosphates from pelves
of kidneys or not.
Cancer cells must not be mistaken for giant
cells with prolongations sometimes ten times
MORPHOLOGY OF THE URINE. 45
their length, and sometimes connecting with
gubernacula two or more giant mucous cells.
Carbonate of lime.
Casts of spermatic ducts, clear or with amy-
loid, phosphate of lime, triple phosphates, etc.
Catarrhal discharges from spermatic ducts or
the prostatic glands :
(i) Protoplasmic.
(2) In skeins.
(3) In Indian clubs.
These occur together at times ; a supposed
cause of neurasthenia in men (Cutter).
Chyme.
Colloid matter.
Cotton, wool, bast, linen fibres, indeed any
form from the morphology of the air may get
in accidentally.
Crypta syphilitica spores.
Cryptococcus xanthogenicus.
Crystals with radiations formed within cells
with amoeboid projections.
Cystin.
Dirt.
Dust.
Eggs of ascarides.
Eggs of trichocephalus dispar.
Epithelia invaded by vegetations of scarlet
fever, diphtheria, typhoid fever, etc., etc.
Epithelia, pavement and columnar, from
bladder and vagina.
Fat in globules.
4-6 MORPHOLOGY OF THE URINE.
Fatty casts of kidney tubes.
Fatty epithelia from kidneys.
Fragments of animal and vegetable tissues.
Giant cells distorted and connected together
by gubernacula — parent mucous cells, proba-
bly simulating cancer cells.
Gemiasma rubra.
Gravel.
Hyaline casts of kidney tubes.
In perfect health, free from deposit or odor,
like healthy nursing infant's urine.
Lactic acid yeasts, spores and filaments.
Mucous cells.
Mucous fibres and casts from kidneys.
Mucous filaments.
Mycelial filaments of mycoderma aceti —
sometimes mother of vinegar.
Other algae.
Oxalate of lime, granular and in dumb-bell.
Penicillium.
Phosphates.
Phosphate of lime.
Pigment matters.
Pus cells.
Putrefactive yeasts in spores and mycelial
filaments. When these are voided from the
bladder, in spores single or aggregated, fila-
ments single or in skeins, I regard it as a
diseased condition, to be treated as such.
Have known epilepsy to be caused by them,
and cured by their removal (Cutter).
MORPHOLOGY OF THE URINE. 47
Radiating plants, same as found in ague soils.
Saccharomyces cerevisiae, or alcohol yeasts.
Spermatozoa, normal.
With two heads.
With three heads.
With two tails.
With three tails, etc.
With two heads and two tails.
With three heads and three tails, etc.
Sphaerotheca spores and filaments.
Starch grains.
Triple phosphates.
Urates of soda and ammonium.
Uric acid.
Vegetations of gonorrhoea.
Vibriones.
Waxy casts of kidney tubes.
Yeasts.
Zoogloea forms.
VI.
THE MORPHOLOGY OF THE
VOMITUS.
Any object of the morphology of foods.
Bile.
Blood.
Butyric acid fermentative vegetations..
Cancerous matters.
Chyme.
Coagulated food.
Colloid.
Cryptococcus xanthogenicus.
Epithelia.
Food partly digested.
Lactic acid yeasts.
Morphology of feces, rare.
Mucous corpuscles.
Mucus.
Mycoderma aceti.
Saccharomyces cerevisiae.
Sarcina ventriculi.
Slime.
Sometimes yeast plants form a coating on
oesophagus, discharged as a membrane.
VII.
MORPHOLOGY OF FOODS,
a. waters of lakes, ponds, and water
sheds; hydrant waters. *
Morphology of animals, plants and other
substances found in hydrant waters and pond
waters, such as are used for drinking purposes.
The list is very incomplete, as more than half
of the objects found have no names (Professor
Paulus F. Reinsch, Erlangen, Ger.).
Over thirty hydrant waters of cities and
towns were studied. Among these were those
of Albany, Brooklyn and New York, New
York; Arlington, Boston, Cambridge, Charles-
town, Haverhill, Charles River, Jamaica Pond
Boston, Lynn, Maiden, Salem, Springfield,
Winchester, Woburn, Worcester, Wellesley
Hotel, Massachusetts ; Philadelphia, Penn. ;
Hartford and New Haven, Connecticut ; Chi-
cago, Illinois; Washington, D. C; Dover,
New Hampshire; Baltimore, Maryland; Cleve-
land, Ohio ; Richmond, Va. Besides ponds in
Amherst, Falmouth, Natick, Holbrook, Wake-
* See page 81 for mode of examination.
So
MORPHOLOGY OF FOODS.
field, West Falmouth, Wellesley, Massachu-
setts ; East Greenwich, Rhode Island, and
North Turner, Maine.
LIST.
A beautiful entomostraca, like the branchippus
stagnalis. (Croton.)
A delicate animal which looks like a snail, and yet
without the terminal of the spiral. It is beautifully
transparent, so that the motion of the heart is more
apparent than in the following. (Croton.)
A magnificent animal composed of a hyaline sac
open at one end. Transparent. Mouth provided
with cilia, which are inverted completely within the
body at will. The viscera are held together byguber-
nacula just outlined enough to be visible. These con-
tract, and keep the viscera moving to and from the
mouth ; specimen name unknown to me ; have found
it only in the Croton.
Abundant mycelial fungus,
filaments.
Acineta tuberosa.
Acropherus.
Actinosphericum Eichor-
nii.
Actinodiscus.
Actinophrys sol.
Alcyonella.
Alonia.
Amblyophis.
Amoeba proteus.
Amoeba radiosa.
Amoeba verrucosa.
Amphiprora alata.
Anabaina circinalis.
Anabaina subtularia.
Anguillula fluviatilis.
Ankistrodesmus falcatus.
Ankistrodesmus unicornis.
Anurea longispinis.
Anurea monostylus with
ovary one-half the dia-
meter of its own body.
Anurea stipitata.
Aptogonum.
HYDRANT AND POND WATERS.
51
Arachnida.
Arcella mitrata.
Arcella vulgaris.
Argulus.
Arthrodesmus convergens.
Arthrodesmus divergens.
Arthronema.
Astrionella formosa.
Bacteria.
Bosmina.
Botryococcus*
Branchippus stagnalis.
Bursaria.
Campanularia.
Campascus carnutus.
Carapace of a monostyled
rotifer, occupied by a
parasitic mother cell
with protoplasmic con-
tents in very active mo-
tion. (Croton.)
Castor.
Centropyxis.
Centropyxis acuelata.
Chetochilis.
Chilomonas.
Chlorococcus.
Chlorogonium.
Chroococcus chalybeus.
Chydorus.
Chytridium.
Cladophora.
Clathrocystis aeruginosa.
Closterium didymotocum.
Closterium lunula.
Closterium moniliferum.
Cochliopodium bilimbo-
sum (Harriman).
Coelastrum sphericurn.
Conf ervoideae.
Cosmarium binoculatum.
Cosmarium crenatum.
Cosmarium tetrophthal-
mum.
Cosmarium margariti-
ferum.
Cristatella mucedo.
Cyclops quadricauda.
Cyclops quadricornis.
Cyphroderia ampulla.
Cypris tristriata.
Daphnia pulex.
Desmidium.
Desmidiaceae.
Diaptomas castor.
Diaptomas castor with sa-
prolegnia attached.
Diaptomas, new species.
Diatoma vulgaris.
Didymocladon.
Difflugia cratera.
Difflugia globosa.
Difflugia lobestoma (Har-
riman).
Difflugia pyriformis.
Dinobryina sertularia.
Dinocharis pocillum.
Dirt.
52
MORPHOLOGY OF FOODS.
Docidium.
Eggs of bryozoa.
Eggs of entomostraca.
Eggs of plumatella.
Eggs of polyp.
Empty shell of arcella.
Enchylis pupa.
Enteromorpha clathrata.
Eosphora aurita.
Epithelia, animal.
Epithelia, vegetable.
Eradne Nordmanni.
Euastrum.
Euglenia viridis.
Euglypha.
Eurycercus lamellatus.
Exuvi'a of some insects.
Feather barbs.
Fish scales.
Floscularia.
Fragillaria.
Fungi.
Fungus, red water.
Gammarus pulex.
Gemiasma verdans.
Globar rotifer.
Gomphospheria.
Gonium.
Grammatophora.
Gregarina saenuridis.
Gromia.
Hairs of plants.
Hairs of various animals.
Heleopera picta.
Holophrya brunnea.
Humus.
Hyalosphenia tincta.
Hyalosphenia formosa.
Hyalotheca.
Hyamodiscus rubicundus.
Hydra vulgaris.
Hydra viridis.
Infusoria.
Insect scales.
Lacinularia.
Lacinularia socialis.
Leaves and parts of leaves.
Leptothrix.
Leucophrys patula.
Licomophora.
Lyngbya.
Masses of sponge paren-
chyma decomposing.
Melosira.
Meresmopedia.
Micrasterias digitata.
Micrasterias denticulata.
Micrasterias rotata.
Microcoleus.
Milnesium tardigradum.
Monactinus octenarius.
Monactinus duodenarius.
Monads.
Mycoderma aceti.
Navicula amphirynchus.
Navicula cuspidata.
Nebalia bipes.
Nitzschia.
HYDRANT AND POND WATERS,
53
Nostoc communis.
Notodelphys
Oedogonium.
Oscillatoriaceae.
Ovaries of entomostraca.
Palmellae.
Pamphagus mutabilis.
Pandorina morum.
Paramecium aurelium.
Pediastrum boryanum.
Pediastrium incisum.
Pediastrium perforatum.
Pediastrum pertusum.
Pediastrum quadratum.
Pediastrum tetras.
Pelomyxa.
Penium.
Peridinium candelabrum.
Peridinium cinctum.
Phacus.
Plagiophrys.
Plagiotoma lumbrici.
Pleurosigma angulatum.
Plumatella.
Pollen of pine.
Polyartha platyptera.
Polycoccus.
Polyhedra tetraetica.
Polyhedra triangularis.
Polyhedrium.
Polyphema.
Polyphemus pediculus.
Protococcus.
Protococcus viridis.
Radiolaria.
Radiophrys alba.
Raphidium duplex.
Rotifer ascus.
Rotifer vulgaris.
Saccharomyces cerevisiae.
Saprolegnia.
Sarcina.
Scales of butterfly.
Scaridium longicaudum.
Scehedesmus acutus.
Scenedesmus obliquus.
Scenedesmus obtusum.
Scenedesmus quadricauda.
Setigera.
Sheath of tubularia.
Silica.
Sphaerotheca spores.
Spicules of sponge.
Spirogyra.
Sponges.
Starch.
Staurastrum dejectum.
Staurastrum furcigerum.
Staurastrum gracile.
Staurastrum margaritace-
um.
Staurogenia quadrata.
Stephanocerus.
Stephanodiscus niagarae.
Spiral tissue, eta
Spirotaenia.
Stentor.
Surirella bifrons.
54
MORPHOLOGY OF FOODS.
Surirella gemma.
Synchoeta.
Sy nhedra.
Synhedra splendens and
many other diatoms too
numerous to name.
Tabellaria.
Tetmemorus granulatus.
Tetraspore.
Trachelomonas.
Triceratium favus.
Trichodiscus.
Tryblionella Scutellaria.
Ulothrix mucosa.
Urococcus.
Urostyla.
Uvella.
Vegetable fibres.
Volvox coenochilus.
Volvox globator.
Volvox, new species.
Vorticel.
Wheat starch grains, etc.
Worm fluke.
Worm, two tailed.
Xanthidium.
Yeast.
APPENDIX.
The bad taste in Cochituate, cause of, discovered in
1879, and in Croton water, discovered in 1 881, to be
due to the presence of spongilla fluviatilis and lacus-
tris and the pelomyxas.
The following facts are adduced in support of this
belief :
1. Spicules of sponge were very abundant in the
Croton during the time of bad taste. These spicules
are most elegant forms of silica that will not polarize
light. They are of various shapes. The most com-
mon one is that of a boomerang shape, exquisitely
pointed at both ends, and polished like steel. An-
other common form in the Croton is shaped, like an
old-fashioned two-tined fork such as is used in a pork
barrel. Some are like the little stand used on the
dining-room tables to keep the blade of the carving
HYDRANT AND POND WATERS. 55
knife off the cloth, etc., etc. Now, this sponge itself
is made up of a jelly-like substance, or sarcode proto-
plasm. When the animal dies, the sponge jelly or pro-
toplasm is dissolved in the water, and goes through all
filtering apparatus. For example, in Woburn, Mass.,
the hydrant water is taken from a gallery by the side
of Horn Pond. Though this water is clear as crys-
tal, if the nostrils be placed over a goblet of it, only a
few sniffs are necessary to perceive the peculiar earthy
smell, though the sense of taste detects nothing wrong.
(Parenthetically, a firm brought suit against this town
for loss of water power by the use of this spring for
drinking purposes. My testimony, that the two wa-
ters were identical by morphological examination,
helped the case for those suing for damages.)
Now an abundance of spicules shows an abundance
of sponges. When Professor Reinsch and myself
were studying the Cochituate water, it was a great
problem to find the sponges from whence these spi-
cules came. It always seemed to me that the minute
spongilli, as found on the rocks of the bottom of
ponds, did not adequately explain the presence of the
sponge spicules, so I kept watching for them, and was
rewarded in 1879.
2. I found in Charles River (Mass.) a fresh-water
sponge that was as thick as my little finger, and be-
tween three and four feet long in linear measure-
ment. Also a clustered mass of sponges in the same
river large enough to fill a two-bushel basket.
Officials connected with the Boston Water Works
have informed me that they have seen like collections
of sponges in the sources of the Cochituate water.
From finding the spicules so abundant in the Croton,
I inferred that there is an abundance of the same
sponges in the sources of the Croton water supply.
56 MORPHOLOGY OF FOODS.
3. A portion of the Charles River sponge kept over
night in a tumbler, in my room at the Wellesley Ho-
tel, stank, in an exaggerated measure, to be sure, as
the filter stank after filtering the Croton water, winter
of 1880-81.
4. About January, 1881, Dr. Harriman, of Boston,
my associate, and myself found portions of dead and
decaying sponges in the Cochituate, they not having
been dissolved. Some of the spicules were actually
sticking out of the mass. The Cochituate had as bad
a taste, and worse, than the Croton at that time.
5. As said before, the great mass of the dead
sponges are soluble in water, and go through all filters.
It seems to me reasonable to partly attribute the
taste and smell to which allusion has been made, to the
presence of sponges. They die and dissolve in the
water, and were it not for the tremendous draft on
the supply, would, no doubt, be all disposed of by the
plants and scavengers living in the water. I am aware
there are some difficulties in the way of this explana-
tion, from the fact that we find sponge spicules at all
seasons of the year, and why, then, should not the
taste be bad all the time ? In reply to this, I refer to
the abundance of the spicules being greater at the
time of the worst taste. I would not be understood
as claiming that the dead sponges are the sole cause of
this taste, as there are a great many rhizopods (root-
footed animals) in the water that die also. They are
protoplasmic, like the sponges. They die, but leave
more solid remains than the sponges. Dr. Har-
riman and myself have noticed especially the pelo-
myxas (pelos, mud, and mukos, mucus) animals made
up of a jelly-like protoplasm, that are very greedy.
They are figured in Dr. Leidy's magnificent work on
the rhizopods, issued by the U. S. government. We
HYDRANT AND POND WATERS. 57
have found them very abundant in the Cochituate and
the Croton when this bad taste was most palpable.
Now as to the question whether the drinking of water
impregnated with dead sponges is healthy. I am sure
no one would have wished to drink the water I had in
my room at Wellesley, fetid with dead sponge ; but as
to the Croton, the chemists decide, I understand, that
the drinking of dead sponges and pelomyxas is not
and cannot be a cause of disease. Now the dicta of
the chemist must he respected, as we have said, and
always shall say ; but when it comes to a question so
subtle as the causes of disease, as a physician I should
hesitate before I pronounced definitely on the question,
for the reason that there is such a great difference in
people as to food. Some people will eat food with
impunity that in other cases acts as a poison to others.
Again, the question of the causes of disease is by no
means settled, and it will be a long time before there
is an agreement. For example, take consumption.
I believe in the Salisbury plan, that it is a disease pri-
marily of the blood, caused by the vinegar yeast.
Though this view is supported by the synthesis of the
disease in hundreds of healthy animals killed by feed-
ing on yeast plants, and the disease verified by exami-
nations after death, by micro-photography of the
forms in the blood, and by the cure of a large number
of persons, still very few of the profession have re-
ceived this view, and have expressed no opinion about
it. So that supposing, for example, the question
should be raised, if the dead sponges in the Croton
water could cause consumption by introducing the
vegetations of decomposition into the human system,
I think a chemist would shrink back from it into his
laboratory, as it would be so difficult, in the present
58 MORPHOLOGY OF FOODS.
state of knowledge in the medical profession, to have
the expression of a decided opinion.
How does the chemist know that dead sponges
do not cause disease ? Diseases do exist, but their aetiol-
ogy is not found in the books of chemistry.
As a physician, I say that the question is still sub
judice. To solve it will require the combined action
of the zoologist, the botanist, the pathologist, and the
practical physician. "But," you say, "we cannot wait
for this ; what shall we do until .the question is de-
cided ?" If a reply is forced, I should say it would
be a very sensible precaution to filter and boil the
water when it tastes badly. The labors of Professor
Reinsch have proved that cotton is king as a filter.
This royal gift is common everywhere.
B. WATERS OF WELLS AND SPRINGS, UNCON-
NECTED WITH PONDS OR LAKES.
Spring IVater from the Farm of Mr. George
Plum, Mantua, Ohio.
Bacteria.
Diatoma vulgaris.
Epithelia from vegetables and animals.
Feather.
Linen fibre.
Mass of vegetable cells, probably of some
berry.
Protococcus.
Silica or sand.
Small masses of dirt.
WATERS OF WELLS AND SPRINGS. 59*
Sphaerotheca, a fungus spore.
Starch.
Woody fibre.
Fitchbtirg Gas Company s JVater, Specimen
Ftirnished by Miss E. IV. Beane, Teacher,
July 16th, 1881.
Bacteria, few.
Cotton fibres.
Epithelial cells.
Leptothrix.
Linen fibres.
Mycelial filaments of a small water fungus.
Tabellaria.
This water has a high local reputation, and
if the present morphological examination is
verified by several more examinations, it must
sustain a very high, if not the highest, reputa-
tion as a drinking water for the public. Here
the work of filtering is done by the everlasting
hills. It is an instance where the nearest ap-
proach to perfection in filtering is seen, provided
the specimen sent is an average sample.
Water from Iron Tube Driven IVell, IVest
Falmouth, Mass. My own.
A few bacteria.
Oil globules.
Particles of dirt.
60 MORPHOLOGY OF FOODS.
Pavement epithelia from human skin, prob-
ably came from the contact of a sewer's fingers
who made the cotton filter.
Scales of oxide of iron.
Starch grains of wheat, that may have come
from the new cotton-cloth filter used.
Epithelia made up most of the organic
forms. The white cotton filter was stained red
with the iron. Depth of well, fourteen feet.
Soil, sandy. Location, within a hundred feet of
the shore of Buzzard's Bay. Water saltish, but
very cool and palatable. Supply, unfailing.
It looks well to the eye.
JV. A. How land 's Weh, same place, Tubular.
Epithelia.
Large vegetable cell, transparent and sur-
rounded by a flat ring.
Ditto, reminding of a cell of orange pulp.
Little dirt.
Mycelial filaments.
Oil globules.
Organic globule.
Starch.
This is nice water, and has agreeable effects
on all the senses. It is down in the cellar of
the house, and is about fourteen feet deep.
WATERS OF WELLS AND SPRINGS. 6 1
IVater from Capt. Hoxie s JVell; Has a Dead
Animal Taste.
Bacteria, abundant.
Dirt, very abundant.
Epithelia in large collections.
Feathers.
Leather from new valve of pump.
Mass of decaying animal matter; dangerous
water.
Monad, alive.
Mycelial filaments of yeast.
Organic globule, unknown.
Oxalate of lime crystal.
Silica.
Starch.
This was a common well, quite deep, and
large enough for a man to get into. Comes
through a lead pipe. Family sick and feeble.
The most striking result is the comparatively
small presence in the springs and wells, namely,
of organic forms of life as compared with the
ordinary ditch, pool, or pond water. Still the
fungi found may be more deleterious to health
than all the forms in Croton, for example.
This is what we are searching for. A member
of the family using the well of Capt. Hoxie has
had the pretubercular stage of consumption, as
shown by physical micrographical explorations.
Also his sputa, urine, and feces have been
62 MORPHOLOGY OF FOODS.
obstinately loaded with vegetation till lately.
We are inclined to think this water has had
something to do with it, and it will be pro-
hibited. The sputa and kidney secretions kept
for a day would be disgustingly fetid, while
both would be loaded with vegetation, excretal.
I never had so obstinate a case before. Neither
diet, sulphur bathing, salicin, or quinine seemed
to affect the abundance of the vegetation until
after three months. Only after the inhalation of
liquid ozone, of Parke, Davis & Co., of Detroit,
did the vegetative solids disappear, but I have no
doubt they would reappear if the use of this water
is continued. I have never met with such an
obstinate case (epileptic, etc.) under the use of
hydrant drinking waters. Have had one case
where the urine was loaded with vegetation as
it left the body. This was a Croton-water
drinker, but diet alone speedily removed the
vegetation.
Water from the well of the late J, F. Davis,
W. Falmouth, Mass.
Bacteria.
Cotton and wool.
Dirt, abundant.
Epithelia, in abundance.
Fungus, spores, ditto, sprouting.
Leptothrix.
ICE. 6
Mycelial filaments very abundant on cul-
ture twenty-four hours.
Woody fibres.
It was said that the chemist's examination
pronounced this well water perfectly pure.
We are not prepared to say that they, the
fungi, caused the sickness in question, but un-
hesitatingly advised the disusing of the water,
for, as Dr. Harriman, my associate, said, " this
abundant presence of fungi shows the presence
of animal matter. At the same time the result
shows the truth of the positions maintained
here, that chemical exploration alone is in-
sufficient for the examination of potable water."
c. ICE.*
MODES OF STUDY.
i. A clean bag, one inch by four inches,
made of cotton cloth, was tied to the escape
pipe of a refrigerator, zinc lined, shelf at top,
that had been washed and cleansed with fil-
tered water. The filtrate of from thirty to
forty pounds of ice was collected by inverting
the detached bag into a clean goblet, then sop-
ping the inverted bag in the filtrate, and wring-
ing the bag also.
2. A common silver ice pitcher, porcelain
lined, was cleaned with filtered Croton water and
* See Scientific American of July 29th, 1882.
64
MORPHOLOGY OF FOODS.
filled with broken ice, source unknown, clear,,
compact, solid, diaphanous, and pure looking.
This was allowed to melt, and one quart of
water resulted, and was filtered as before.
Power of microscope, one-fifth inch objec-
tive. Eye-piece, one inch and half-inch, 35a
diameters.
Many of the following list come from the
air ; perhaps half. Some of the specimens of
ice came from ice wagons ; one from a provi-
sion store. This is, of course, a partial list.
Acanthodinium, with clus- Closterium.
ters of twelve spiral
cells separated in all di-
rections.
Actinophrys sol.
Alcohol yeast.
Amoeba, alive.
Anuroea monostylus.
Ascus.
Astrionella formosa.
Bacillaria diatom.
Bacteria.
Bast fibres.
Botridium cells.
Broken down tegument
and substance of leaves.
Bryozoa, egg of.
Carbon.
Chitin.
Chlorococcus.
Claw of water spider.
Claws of insects.
Closterium lunare, dead.
Closterium, young.
Coal.
Coelastrum sphericum.
Collection of liber fibres.
Cotton fibre.
Corn starch.
Cryptomonas lenticularis.
Daphne claws.
Dark-red organic un-
known body.
Decaying leaves.
Desmid, penium.
Diatoma, not named.
Diatoma vulgaris.
Diatomaceae, other.
Diflflugia.
Diffiugia, dead, several
varieties.
Diffiugia globosa.
Diffiugia, unusual.
ICE.
65
Dinobryina sertularia.
Dirt, debris, etc.
Dust and excrementitious
matters.
fcgg of the fresh water
polyzoa named below,
unhatched.
Eggs of entomostraca.
Epidermis of wheat.
Epilobium montanum
pollen.
Epithelia, animal and ve-
getable.
Epithelial scales, human.
Euglenia viridis.
Euglypha.
Euglypha cristata.
Exuvium.
Feather barb.
Fibre of wool colored
blue.
Fish scales.
Foot stalks of vorticelis,
twenty-five in number.
Fungi and spores.
Fungus filament.
Gemiasma verdans.
Gluten cells, wheat.
Gromia.
Hairs of plants.
Hairs of various animals.
Humus.
Large double body, prob-
ably eggs, but possibly
vegetable.
Large masses of decaying
vegetable substances.
Large paramecia.
Leaves of moss.
Leptothrix.
Liber fibres.
Linen fibre imbedded in a
mass of decaying vege-
table substance.
Linen fibres.
Lyngbya.
Mass of carbon.
Melosira.
Membrum disjectum of a
large entomostraca.
Monads.
Mycelial filaments, abun-
dant.
Mycelial filaments, collec-
tion of.
Mycelial filaments of red
water fungus.
Navicula.
Nebalia.
Nostoc.
One gonidia of coelastrum
sphericum.
Oscillatoria.
Parenchyma of leaf.
Parenchyma of wheat.
Pavement epithelia, five
specimens.
Pediastrum boryanum.
Pelomyxas, other,
Peridinium cinctum.
66
MORPHOLOGY OF FOODS.
Peridinium spiniferum.
Piece of a red cranberry
skin.
Pitted duct?.
Polyzoa.
Portion of a leaf with
chlorophyll attached,
color unchanged.
Portion of a red water
fungus.
Potato starch.
Protococcus.
Protococcus, probably ge-
miasma.
Rotifer.
Scenedesmus obliquus.
Scenedesmus quadricauda.
Shell of a Cyprus.
Silica.
Silk fibre.
Skeleton of leaves.
Sphaerotheca fungus.
Spiral tissues of leaf.
Starch of corn, wheat, and
potato.
Staurastrum.
Supposed egg of an ento-
mostraca.
Tabellaria.
Tetraspore.
Trachelomonas.
Transverse woody fibre.
Vegetable epithelial col-
lection.
Vegetable hair, long.
Vegetable hairs.
Vorticell, dead.
Vorticella, two joined to-
gether.
Wheat gluten cells.
Wheat starch.
Wood fibre of
kinds.
Wool.
Worm.
Yeast, alcohol,
and lactic acid.
Yeast, vegetating
ments.
various
vinegar,
fila-
Ice from Horn Pond, Woburn, Mass. This pre-
sented considerable lightish colored deposit, in which
a few animal and vegetable forms were found, but was
mainly made up of epithelia and amorphous dirt.
The result was unexpected, as unfiltered Horn Pond
water is rich in forms of life.
ICE. 67
APPENDIX.
In this article of mine in the Scientific American,
as before noted, there were illustrations to the number
of eight. I give, as follows, some of the descriptive
text of those illustrations :
Yeast. — This is the alcohol yeast of the yeast pot,
torula cerevisise, the spores of which are everywhere
present, ready to germinate if they have the opportu-
nity. Its presence in ice is interesting.
Bacteria. — These are minute, self-moving protoplas-
mic bodies. Some regard them as ultimate forms of
life ; others that they are but the embryonal forms,
seeds, or babies (as it were) of a vegetation, yet capa-
ble of immense reproduction by division, arranging
themselves into masses, chains, etc., at will. In order
to know what plants they belong to, culture is neces-
sary. It is possible that those in the cut may be the
spores or seeds of the yeast plants, but it cannot be
said with certainty.
Pelomyxa. — This means " mud mucus." It is an
animal classed with the rhizopod or root-footed pro-
toplasmic animals. They are very greedy, and eat
much mud or dirt. The color in this case is dark am-
ber, and may be mistaken for decaying vegetable mat-
ter. The writer regards them with suspicion, as con-
tributing, when dead and decaying, to cause the
"cucumber" and fish-oil taste that sometimes occurs
in hydrant drinking waters, notably the Cochituate.
Portions of DifBugia. — These are like the pelomyxse,
only they have the property of building over them-
selves a covering made of particles of sand, glued to-
gether so as to protect their structural protoplasmic
68 MORPHOLOGY OF FOODS.
bodies. Lately, the writer saw a difflugia craterar
whose shell had been broken on one side. The cilia
that were usually seen at the natural opening were
seen to be active at the artificial opening. The con-
tour of the hole changed under view from circular to
a narrower one, forming a segment of the first, show-
ing an action of repair ; suddenly there was a gush of
protoplasmic jelly, and the animal was dead, dying in
its efforts of reconstruction.
Mycelial filaments of a red fungus, found commonly
in Horn Pond, Woburn, Mass. Also at Cambridge.
Name not known to writer, nor Prof. Reinsch.
A curious dark-red tubular body, fragments of which
I have often seen in hydrant drinking waters. Its
fracture is glassy. It is an animal substance probably,
and this is the best specimen I have seen.
Trachelomonas. — These are by Ehrenberg claimed
as infusoria. They are very abundant in hydrant
waters at all seasons of* the year. The specimen here
is dead, but the .living individual moves its curious
long flagelliform filament, by means CFf which it
gracefully propels itself in any direction at will.
Astrionella Formosa. — A beautiful, very common
diatom, that arranges itself into forms like the spokes
of a wheel. Three spokes only are given here ; usu-
ally twelve. This power of self-symmetrical arrange-
ment is surprising and mysterious.
Bast or Linen Fibre. — This probably came from
some table cloth, towel, or clothing.
An ascus or theca of a fungus, which is a part of
a fructification of the fungus, and also found in
lichens. It is strikingly well-developed.
Epithelia, probably animal. — These are suspicious
organisms. See New York Medical Record, April
8th, 1882.
ICE. 69
Egg of a bryozoa or polyzoa, found not unfre-
quently in the drinking waters of our cities and towns.
It corresponds to the " winter egg1' of entomostraca.
It forms one of the four modes of reproduction, which
Smith distinguishes : First. Eggs from spermatozoa.
Second. From internal development (this very one).
Third. External buds. Fourth. Brown bodies in
empty eggs. This particular egg is seen to have an
oval opening, whence the contents have been hatched
or destroyed. It has been traced to a single polyp.
Usually the animals live in a colony, and are met with
in fresh water on stones, sticks, sides of flumes, and
free. I have seen colonies of these bryozoa in masses
as big as a bushel basket, hanging on and covering the
perpendicular boards of a flume. In the present case,
the egg is nearly as la^ge as the animal in a state of
rest. Its detection shows decidedly the presence of
animal life in ice.
Dirt is hard to picture, but should have a place in
this morphology, though it has been defined as "mat-
ter out of place."
Tabellaria. — Diatom found commonly in all sur-
face drinking waters. They have the power to arrange
in rows, and the specimen has fifteen individuals in
one aggregation, which is a small one. Diatoms are
regarded as plants by the majority of observers. A
good deal of difficulty arises from trying to measure
things with the lines and plummets of past times,
when the things in question were absolutely unknown,
and hence could not be properly named at the date
when the word " plant " was invented. As knowledge
increases, names must be changed. The diatoms are
generally regarded as innocent, though some observ-
ers take the opposite ground.
Epithelia. — These are probably human, washed into
yO MORPHOLOGY OF FOODS.
the water, and frozen into the ice. They are con-
stantly thrown off in washing, sputa, and the excre-
tions of the body. They are also found on all other
vertebrate animals and on vegetables.
" Mycelial filaments of a vinegar yeast found in con-
nection with melting ice. At the bottom are the em-
bryonal spores of the yeast." — Scientific American, p.
73, col. 2.
This shows what happens when ice-water is allowed
to stand exposed to the action of the air. A long,
dirty, grayish, gelatinous ribbon, half an inch wide and
about one-eighth inch thick, appeared to be a mass of
what is called "the mother of vinegar." The cut gave
the appearances under the microscope. The signifi-
cance shows what is the full development of some of
the embryonal forms of life found in ice-water when
subjected to conditions that are present in refrigera-
tors.
It must be remembered that these are not the full
lists of what were examined. Some could not be
named. Neither can it be said here that it has been
settled that ice is injurious or not. But enough testi
mony is here given to indicate that ice should not be
used in water ; but if the water must be cooled, let it
be done by placing jars of water in ice.
D. AIR.
The idea that air is food is found in Hindu-
stanee language of three thousand years ago.
The word animal infers air to sustain life. If
any one doubts this position as to air being;
food, let him hold his breath for five minutes.
AIR. 71
There are many ways to study this mor-
phology, among which are :
1. Moisten the cleaned tip of one's finger
with distilled or filtered water, or water whose
morphology is known, then touch it to the top
of some article of furniture. Instantly the tip
will be covered with dust or forms that have
mounted through the air to rest where found.
This dust can be transferred to a slide, covered,
and examined. I think this the quickest and
easiest mode.
2. Ice. Let a piece of ice melt in the air to
be examined. Instantly there is a current of
air towards it bearing the forms against the
moist surface of the ice ; they stick, and can be
removed on to a slide, covered, and examined
under the microscope. Or, the ice may be
allowed to melt in a vessel, and the resultant
water explored as in water examinations.
3. Exposure of slides moistened with glycerin
or not, with or without a cone attached to a
vane, so that the air impinges on the slide.
4. Air may be filtered through a cotton bag,
and then the bag reversed and washed in fil-
tered water.
5. A slide may be placed on a flat surface, or
on pins or legs, so as to catch the forms that
fall or that are forced from below, as in ague
districts.
6. Snow may be taken in a can or pail, or
any receptacle that has been cleaned with dis-
J2 MORPHOLOGY OF FOODS.
tilled or filtered water. The snow allowed to
melt, and the water filtered ; the filtrate will be
found to contain many forms.
It is astonishing how the air in motion will
carry solids. In San Francisco, I saw sand
from the Pacific Ocean dried and blown in such
quantities as to go over houses and bury street
lamps. I have read of moving mountains of
sand. Perhaps the writer may say that he
writes on the eighth floor of a large apartment
house, where he expected to be free from the
dust which annoyed him at a past residence on
the second floor, but the fact is, his microscope
glass table is covered in one day as much as
in three at the former residence. Such facts
deserve attention of those who study malaria,
and such must expect to find the morphology
of the air mixed with the other morphologies ;
still it will not do to attribute to the air things
that belong to other morphologies. The carry-
ing properties of air are underestimated by
people not housekeepers.
The morphological study of the air prepares
one to be careful in rejecting evidence which
shows the route of invasion of diseases by the
medium of the atmosphere through the air
passages.
Ague plants.
Algae.
All dusts from soils.
Anything that comes from the wear and tear
air. 73
of the multitudinous operations of life every-
where, whether dried and blown by currents of
wind, or by heat, or diffusion of gases.
Asthmatos ciliaris.
Automobile spores.
Bi-acicular crystals, etc.
Coal.
Cotton.
Crystals of chloride of ammonium.
Diatoms.
Epithelia.
Fat globules.
Feathers of birds and insects.
Fungi spores and macrospores.
Hairs of animals and plants.
Insects and parts of insects.
Leather.
Linen fibre.
Palmellae.
Paper.
Pigment matters.
Pollens of plants.
Pus.
Silica.
Smoke products.
Sphaerotheca pyrus.
Spores and young plants of:
Protuberans gelatiformis.
Protuberans lamella.
Protuberans ovalis, with dried incrusta-
tions of the same.
74 MORPHOLOGY OF FOODS.
Spores of cryptogamic vegetations of the
sick carried by the sweat
Starches.
Vibriones.
Volcanic dust.
Winged seeds, etc.
Woody fibre.
Wool.
Yeast spores, alcoholic, lactic acid, butyric-
acid, etc.
Zoospores
E. MORPHOLOGY OF FOODS, ANIMAL AND
VEGETABLE.
The limits of this work having been ex-
ceeded, only a passing allusion can be made to
this large, fruitful and important field, which is
close at hand, easily manipulated and intensely
interesting and profitable. There are four
phases in which the morphology should be
studied.
i . Uncooked.
2. Cooked.
3. After migration throtigh the alimentary
canal.
4. Adulterations.
1. UNCOOKED.
For example, take the potato ; its skin, cortical
substance and parenchyma should be studied in
ANIMAL AND VEGETABLE. 75
thin sections, and all the forms noted, whether
the names are known or not. Among these
are the epithelia, cork cells, connective fibrous
tissues, spiral tissue, pitted ducts, gubernacula
leading from the " eyes" to the centre of the
parenchyma, the reticulation of a cross section,
the starch grains filling such a section, as eggs
in a basket, the various sizes, shapes, concen-
tric markings of the starch grains, the action of
the polarized light on the starch and cellulose,
etc., etc.
2. COOKED.
By boiling, steaming, or action of hot fat.
See if the starch polarizes the light ; if so, the
potato is not fully cooked. See the sacs of the
potato substance embracing the starch grains,
which, if well cooked, should be converted into
a homogeneous mass all mixed up together,
with no sign of the uncooked egg-shaped
forms they had before cooking.
3. EXAMINED IN THE FECES
Of the eater ; if any of the sacs are found,
that have not been digested, the clinical exam-
iner must study to find out if the fault lies
with the alimentary canal, which has allowed the
potato sacs to traverse it undigested. If the
contents of the sacs are not broken up or homo-
geneous, and do not polarize light, the fault
j6 MORPHOLOGY OF FOODS.
must lie with the digestive apparatus. Gener-
ally, when a food that is properly cooked, or
raw, runs through the alimentary canal
intact, it should be avoided. It is folly to give
the digestive system problems which it is un-
able to solve. Better change to something
else that will digest or administer such reme-
dies as will make them digest. Here is a
beautiful field of study ; I say beautiful, be-
cause its lessons are so clear and instructive,
and because some of the finest specimens of
polarized light are found in the feces.
As to beef-steak.
1. Uncooked, note its beauty under polarized
light, the trichinae (if present), the physical ap-
pearances of the fibrillar, the amount of fatty
infiltration, the amount of connective tissue,
etc., etc.
2. Cooked. — The shrinking in size, the ab-
sence of polarization, the darkened color ap-
proaching black.
3. In the feces, if not broken up into a fine
homogeneous mass, like a solid extract in which
no forms of muscular fibre can be detected, it
is not thoroughly digested. If the muscular
fibres are found undigested, they tell their own
story plainly.
It must be remembered that the connective,
areolar, and fibrous tissues from the vegetable
ADULTERATION. 7 "J
kingdom are almost all insoluble in the juices
of the alimentary canal, and must be expected
to appear in the feces of healthy digestion.
The above list might be extended by includ-
ing celery, cranberries, grapes, peaches, wheat,
oats, barley, rye, melon, specially watermelons,
which show beautifully protoplasm in active
motion, tomatoes, corn, squash, sweet potatoes,
mustard, bread of all kinds, cake, crackers,
pilot bread, unleavened bread, wines, dough,
yeast from sour bread, etc., etc., etc.
The use of the polariscope is invaluable as a
test for cooking. The writer has used it for
many years, and was probably the first to call
attention to its great value as a test for
cooking. The morphology of foods throws
great light on the alcohol question.
4. ADULTERATION OF FOODS.
This department would fill a book, but atten-
tion can only be called to it here. So long as
money can be made by false dealings as to
foods, just so long is there need of protection
by a knowledge of the morphology of adultera-
tions of foods.
The statements of the interested parties
should be tested by the microscope. For ex-
ample, if an article claims to be pure coffee, it
should prove to be so under the microscope.
A study of a genuine grain of coffee will give
yS MORPHOLOGY OF FOODS.
the clues, and a study of chicory will also be of
help, as it is generally used for adulteration of
coffee. Indeed, the adulterations of all spices,
black pepper, for example, with ground button-
wood bark, have been going on for years, and
will probably go on till this subject is properly
understood, and this will be when microscopes
are as common as pianos and organs. May
this time soon come !
The morphology of food is easiest of all to
study, and no one should give decided opinions
before practical knowledge is acquired ; those
who have never had their attention called to
this subject, will find its investigation to be a
great revelation as to human nature.
Infants Foods.
The writer must content himself with refer-
ring to his monograph on this subject, which
will be furnished on application to him. It is
sufficient to say here that most of them fall
short of their claims, and should be given a
wide berth. Far better is it to feed during
motherhood so that there shall be an abun-
dance of healthy milk, to wit : two-thirds ani-
mal and one-third vegetable food (see "Food in
Motherhood," by author, about to appear), and
then there will be no need of artificial feeding
of infants.
Should this present work be encouraged by
INFANTS FOODS. 79
the profession, the writer will give a fuller
treatment of the morphology of foods, which
will involve considerable expense of time, labor,
and money, and which, by good right, should
not be done by private enterprise, but under
governmental patronage, because it has the
most intimate relations to the welfare of its
most precious articles of value in the nation, to
wit : the human beings within its confines.
VIII.
MORPHOLOGY OF CLOTHING.
This is a practical question, showing how to
have no cheats in clothing ; but it assumes a
more intense interest in its medico-legal rela-
tions, for example, the examination of blood
stains on coats, shirts, pockets, money bags,
greenbacks, etc., etc.
Everything found in the morphology of the
air and dirt must be expected here, added to
the morphology of dried blood. Careful men-
suration and inspection of the suspected blood
must be made amid the crowd of other objects,
such as silica, feathers, starch of all kinds, pollen
of many kinds, pigment matters, hairs of plants
and animals, fibres of textile fabrics, animal and
vegetable tissues, fungi and algae, and so forth.
Corpuscles of various shapes distorted in
drying or not may be found. Now and then,
perfect ones can be found alone, or buried
wholly or in part in the clot.
When the stains have been washed with
water to remove them, as water is the best
thing for this purpose, the morphology is still
MORPHOLOGY OF CLOTHING. 8 1
more difficult. Yet making allowance for this
bleaching detergent process, much valuable
information can be had which, while it does not
positively convict or release, points the way out
to conviction or not, as the case may be, very
strongly in doubtful cases. In our present
state of knowledge, no one should be hung or
set free simply upon the blood evidence alone,
unless the claim is made that the blood stain is
one of the bird family, whose corpuscles are
oval and whose white corpuscles are smaller
than the red. The microscope should not be
made to prove more than belongs to its domain.
To examine water morphology/" filter through cot-
ton bag, about one and one-half by four inches, with
as gentle a pressure as possible. When the water
begins to bore through in jets, stop flow. Remove
bag, empty into a goblet, turn bag inside out and sop
in goblet a short time. Squeeze bag by twisting.
With a pipette remove specimens on to a slide and
cover, or, better, have a slide with an open cell, two
by two-thirds inch, one-eighth inch deep, and place
specimen on horizontal stage ; one inch, one-quarter
to one-tenth inch objectives.
*See pages 49 and 58.
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